Data transmission method and data transmission apparatus

ABSTRACT

A data transmission apparatus for relaying data transmitted from the transmitting end in units of packets, each packet having additional information relating to its sequence number, priority and data reproduction time, comprises: a receiving unit for receiving packets transmitted from the transmitting end; a priority decision unit for deciding the priority of each of the received packets; a retransmission packet storage unit for storing packets the priorities of which are equal to or higher than a predetermined value, as retransmission packets, on the basis of the priority of each packet decided by the priority decision unit; a retransmission instruction receiving unit for receiving a retransmission request from a terminal at the receiving end; a retransmission decision unit for deciding whether retransmission of the packet for which the retransmission request has been made should be performed or not, on the basis of the retransmission request and the storage status of the retransmission packets in the retransmission packet storage unit a transmission queue management unit for setting the transmission order of the received packets and the packets which have been decided as packets to be retransmitted, on the basis of additional information which is given to each packet; and a transmission unit for transmitting the data of these packets in the transmission order set by the management unit. Therefore, the transmission quality in a radio section in real-time transmission is improved and, further, the number of retransmission times is reduced.

FIELD OF THE INVENTION

[0001] The present invention relates to data transmission methods datatransmission apparatuses, data receiving apparatuses, and a packet datastructure and, more particularly, to a process of performing datatransmission in packet units between a distribution server and aterminal while successively reproducing the data of received packets atthe terminal.

BACKGROUND OF THE INVENTION

[0002] For transmission of video (audio and video) data on the Internet,a download type transmission method and a stream type transmissionmethod are currently employed.

[0003] In the download type transmission method, a video filetransmitted from a distribution server is once copied at the terminaland, thereafter, data of the video file (video data) is reproduced. So,the terminal cannot perform data reproduction until the filetransmission is completed. Therefore, the download type transmissionmethod is not suitable for long-hours of reproduction of video data orthe like.

[0004] On the other hand, in the stream type transmission method, whilevideo data or the like is transmitted from a distribution server to aterminal, received data is reproduced at the terminal.

[0005] Recently, a stream type transmission method using a protocolcalled RTP (Real-time Transport Protocol) which is defined in IETE RFC1889, has mainly been used.

[0006]FIG. 28(a) is a diagram for explaining a video data transmissionmethod according to the RTP.

[0007] With reference to FIG. 28(a), a distribution server (transmittingend) and a terminal (receiving end) such as a personal computer areconnected by a cable in the Internet, such as modem, ISDN, or LAN, andtransmission of video data is carried out between the server and theterminal by using the RTP.

[0008] In the data transmission according to the RTP, processes for therespective packets are synchronized between the transmitting end and thereceiving end by using time stamps as time information, and asynchronous(late arrival) packets and packets affected by transmission errors arediscarded at the receiving end. Further, discarded or lost packets aredetected at the receiving end, according to the absence of sequencenumbers give to these packets.

[0009] On the other hand, Internet applications utilizing mobile phones,for example, mail access and text information service, are advancingnow, and infrastructure for high-speed radio data communication(high-speed packet communication of ˜384 kbps) is under preparation forpractical use of the third generation mobile communication (W-CDMA: Wideband-Code Division Multiple Access).

[0010]FIG. 28(b), is a diagram illustrating a communication network forthe above-described W-CDMA visual terminal.

[0011] Such communication network includes a radio transmission section.For example, when performing data transmission between a videodistribution server and a visual terminal through a relay server, thesection between the distribution server and the relay server is a cabletransmission section by the Internet, but the section between the relayserver and the visual terminal is a radio transmission section by amobile phone network such as the W-CDMA.

[0012] However, the bit error rate in the radio transmission section is10⁻³ while the bit error rate in the cable transmission section is10⁻⁵˜10⁻⁷, and the radio transmission quality becomes a problem in theRTP type data transmission method in which the reproduction qualitydepends on the end-to-end (server-to-terminal) transmission quality.

SUMMARY OF THE INVENTION

[0013] The present invention is made to solve the above-describedproblems and has for its object to provide a data transmission method, adata transmission apparatus, and a data receiving apparatus, which canimprove the transmission quality in a radio section in real-timetransmission.

[0014] Other objects and advantages of the invention will becomeapparent from the detailed description that follows. The detaileddescription and specific embodiments described are provided only forillustration since various additions and modifications within the scopeof the invention will be apparent to those of skill in the art from thedetailed description.

[0015] According to a first aspect of the present invention, there isprovided a data transmission method for performing continuous datatransmission from the transmitting end to the receiving end in units ofpackets, each packet having additional information relating to itssequence number, priority, and data reproduction time at the receivingend, while successively reproducing data of packets received at thereceiving end. This method comprising the steps of: at the transmittingend, giving priority information to each packet to be transmitted; andstoring, as retransmission data, only data of packets the priorities ofwhich are equal to or higher than a predetermined value, in aretransmission buffer; at the receiving end, when a transmission erroris detected, detecting the priority information of an error packet; andwhen the detected priority is equal to or higher than the predeterminedvalue, outputting a retransmission request for the error packet to thetransmitting end by indicating the sequence number of this error packet;at the transmitting end, only when the data of the packet having thesequence number which is indicated by the retransmission request fromthe receiving end is stored in the retransmission buffer, retransmittingthe data of this packet to the receiving end; and discarding the datastored in the retransmission buffer in order starting from a packetwhich cannot be in time for data reproduction at the receiving end.Therefore, the transmission quality in a radio section in real-timetransmission is improved and, further, the number of retransmissiontimes is reduced.

[0016] According to a second aspect of the present invention, in thedata transmission method of the first aspect, when the retransmissionbuffer is filled up to its capacity, an updation process is performed,in which the retransmission data are retained while the data stored inthe retransmission buffer are discarded in order, starting from a packetof the earliest reproduction time, on the basis of the reproduction timeof each packet stored in the retransmission buffer. Therefore, thetransmission quality in a radio section in real-time transmission isimproved and, further, the number of retransmission times is reduced.

[0017] According to a third aspect of the present invention, in the datatransmission method of the first aspect, when the data transmitted fromthe transmitting end to the receiving end is video data based on MPEG, apacket which contains data corresponding to frames coded by utilizingintra-frame correlation is regarded as a packet having a high priority.Therefore, the transmission quality in a radio section in real-timetransmission is improved and, further, the number of retransmissiontimes is reduced.

[0018] According to a fourth aspect of the present invention, in thedata transmission method of the first aspect, at the transmitting end,the additional, information relating to the sequence number and thepriority of a predetermined packet is also embedded in a subsequentpacket to be transmitted after the predetermined packet; and at thereceiving end, in the case where a transmission error has occurred inthe predetermined packet an the additional information of thepredetermined packet has an error, a retransmission request for thepredetermined packet as an error packet is made on the basis of theadditional information of the predetermined packet which is embedded inthe subsequent packet, when the subsequent packet transmitted after thepredetermined packet is received. Therefore, the transmission quality ina radio section in real-time transmission is improved and, further, thenumber of retransmission times is reduced.

[0019] According to a fifth aspect of the present invention, in the datatransmission method of the fourth aspect, at the transmitting end, theprocess of embedding the sequence number of a predetermined highpriority packet in a subsequent packet which follows the predeterminedhigh priority packet is continuously performed until a high prioritypacket next to the predetermined high priority packet is transmitted;and at the receiving end, the sequence number of another packet which isembedded in the received packet is extracted, and when a transmissionerror has occurred in the packet of the extracted sequence number, aretransmission request for this error packet is made by indicating thesequence number of this packet. Therefore, the transmission quality in aradio section in real-time transmission is improved and, further, thenumber of retransmission times is reduced.

[0020] According to a sixth aspect of the present invention, there isprovided a data transmission apparatus for relaying data which aresuccessively transmitted from the transmitting end in units of packets,each packet having additional information relating to its sequencenumber, priority, data reproduction time at the receiving end. Thisapparatus comprises: a receiving unit for receiving the packetstransmitted from the transmitting end; a priority decision unit fordeciding the priority of each of the received packets; a retransmissionpacket storage unit for storing packets the priorities of which areequal to or higher than a predetermined value, as retransmissionpackets, on the basis of the priority of each packet decided by thepriority decision unit; a retransmission instruction receiving unit forreceiving a retransmission request from a terminal at the receiving end;a retransmission decision unit for deciding whether retransmission ofthe packet for which the retransmission request has been made should beperformed or not, on the basis the retransmission request and thestorage status of the retransmission packets in the retransmissionpacket storage unit transmission queue management unit for setting thetransmission order of the received packets and the packets which havebeen decided as packets to be retransmitted, on the basis of theadditional information; and a transmission unit for transmitting thedata of these packets in the transmission order set by the managementunit. Therefore, only the error packets the priorities of which areequal to or higher than a predetermined value can be retransmitted,whereby the transmission quality of radio section in real-timetransmission is improved and, further the number of retransmission timesis reduced.

[0021] According to a seventh aspect of the present invention, there isprovided a data receiving apparatus for receiving data which aretransmitted from the transmitting end in units of packets, each packethaving additional information relating to its sequence number, priority,and data reproduction time at the receiving end, and successivelyreproducing the data for each packet. This apparatus comprises: areceiving unit for receiving the packets transmitted from thetransmitting end; an error packet detection unit for detecting errorpackets in which errors have occurred during transmission, andoutputting normal packet which have been transmitted withouttransmission errors, on the basis of the data of the received packets; apacket priority decision unit for receiving the output from the errorpacket detection unit, and deciding error packets the priorities ofwhich are equal to or higher than a predetermined value; and aretransmission instruction output, unit for outputting a retransmission,request for each of the error packets the priorities of which aredecided as being equal to or higher than the predetermined value, to thetransmitting end, by indicating the sequence number of this errorpacket. Therefore, at the receiving end, a retransmission request to thetransmitting end is made only for the error packet the priority of whichis equal to or higher than a predetermined value, whereby thetransmission quality in a radio section in real-time transmission isimproved and, further, the number of retransmission times is reduced.

[0022] According to an eighth aspect of the present invention, there isprovided a data transmission method in which data transmission from thetransmitting end to the receiving end is continuously performed in unitsof packets, each packet having additional information relating to itssequence number, priority, and data reproduction time at the receivingend, while successively reproducing data of packets which have arrivedat the receiving end and, at this time, only packets which can be intime for data reproduction at the receiving end are retransmitted Thismethod comprises the steps of: at the transmitting end, giving a datareproduction time at the receiving end to each packet to be transmitted;and storing, as retransmission data, only data of packets the prioritiesof which are equal to or higher than a predetermined value, in aretransmission buffer; at the receiving end, when a transmission erroris detected, detecting the reproduction time for an error packet and thearrival time of the error packet, and deciding an arrival time limit inaccordance with the reproduction time; and when the error packet hasarrived before the arrival time limit, outputting a retransmissionrequest for the error packet to the transmitting end by indicating thesequence number of this error packet; at the transmitting end, when thedata of the packet having the sequence number indicated by theretransmission request from the receiving end is stored in theretransmission buffer, retransmitting data of the packet thetransmission time of which does not pass the reproduction time, to thereceiving end, while discarding data of the packet the transmission timeon which has passed the reproduction time; and discarding the datastored in the retransmission buffer in order starting from a packetwhich cannot be in time for data reproduction at the receiving end.Therefore, the transmission quality in a radio section in real-timetransmission is improved and, further, the number of retransmissiontimes is reduced.

[0023] According to a ninth aspect of the present invention, in the datatransmission method of the eighth aspect, when the retransmission bufferis filled up to its capacity, an updation processes is performed, inwhich the retransmission data are retained while the data stored in theretransmission buffer are discarded in order, starting from a packet ofthe earliest reproduction time, on the basis of the reproduction time ofeach packet stored in the retransmission buffer. Therefore, thetransmission quality in a radio section in real-time transmission isimproved and, further, the number of retransmission times is reduced.

[0024] According to a tenth aspect of the present invention, in the datatransmission method of the eighth aspect, the arrival time limit isdecided based on at least one of the allowable packet delay time decidedat the receiving end, and the packet transmission delay time between thetransmitting end and the receiving end. Therefore, the transmissionquality in a radio section in real-time transmission is improved and,further, the number of retransmission times is reduced.

[0025] According to an eleventh aspect of the present invention, in thedata transmission method of the eighth aspect, at the transmitting end,additional information relating to the sequence number and thereproduction time corresponding to a target packet to be transmitted isembedded in a subsequent packet to be transmitted after the targetpacket; and at the receiving end, when a transmission error of thetarget packet has occurred and the additional information of the targetpacket has an error, a retransmission request for the target packet asan error packet is made on the basis of the additional information ofthe target packet which is embedded in the subsequent packet, when thesubsequent packet transmitted after the target packet is received.Therefore, the transmission quality in a radio section in real-timetransmission is improved and, further, the number of retransmissiontimes is reduced.

[0026] According to a twelfth aspect of the present invention, there isprovided a data transmission apparatus for relaying data which aresuccessively transmitted from the transmitting end in units of packets,each packet having additional information relating to its sequencenumber, priority, data reproduction time at the receiving end. Thisapparatus comprises: a receiving unit for receiving the packetstransmitted from the transmitting end; a priority decision unit fordeciding the priority of each of the received packets; a reproductiontime decision unit for deciding packets which cannot be in time forreproduction at, the receiving end, amongst the packets to betransmitted to the receiving end; a retransmission packet storage unitfor storing packets the priorities of which are equal to or higher thana predetermined value, as retransmission, packets, on the basis of thepriority of each packet decided by the priority decision unit; aretransmission instruction receiving unit for receiving a retransmissionrequest from a terminal at the receiving end; a retransmission decisionunit for deciding whether retransmission of the packet for which theretransmission request has been made should be performed or not, on thebasis of the retransmission request and the storage status of theretransmission packets in the retransmission packet storage unit; atransmission queue management unit for setting the transmission order ofthe received packets and the packets which have been decided as packetsto be retransmitted, on the basis of the additional information; and atransmission unit for transmitting, in the transmission order set by themanagement unit, the data of packets other than the packets which aredecided as packets that cannot be in time for reproduction at thereceiving end, by the reproduction time decision unit. Therefore, thetransmission quality in a radio section in real-time transmission isimproved and, further, the number of retransmission times is reduced.

[0027] According to a thirteenth aspect of the present invention, thereis provided a data receiving apparatus for receiving data which aretransmitted from the transmitting end in units of packets, each packethaving additional information relating to its sequence number, priorityand data reproduction time at the receiving end, and successivelyreproducing the data for each packet. This apparatus comprises: areceiving unit for receiving the packets, transmitted from thetransmitting end; an error packet detection unit for detecting errorpackets in which errors have occurred during transmission, andoutputting normal packets which have been transmitted withouttransmission errors, on the basis of the data of the received packets; areproduction time decision unit for detecting the reproduction timegiven to each error packet detected by the error, packet detection unitand the arrival time of the error packet at the receiving end, andsetting the arrival time limit based on the reproduction time, anddeciding whether or not the error packet has arrived at the receivingend before the arrival time limit; and a retransmission instructionoutput unit for outputting a retransmission request only for the errorpacket which has arrived at the receiving end before the arrival timelimit, to the transmitting end, by indicating the sequence number of theerror packet, on the basis of the result of the decision in thereproduction time decision unit. Therefore, the transmission quality ina radio section in real-time transmission is improved and, further, thenumber of retransmission times is reduced.

[0028] According to a fourteenth aspect of the present invention, thereis provided a data transmission method for performing continuous datatransmission from the transmitting end to the receiving end in units ofpackets, each packet having additional information relating to itssequence number, priority, and data reproduction time at the receivingend, while successively reproducing data of packets arrived at thereceiving end. This method comprises the steps of: at the transmittingend, giving a data reproduction time and priority information to eachpacket to be transmitted; and storing, as retransmission data, only dataof packets the priorities of which are equal to or higher than apredetermined value, in a retransmission buffer; at the receiving end,when a transmission error is detected, detecting the priorityinformation of an error packet, the reproduction time of the errorpacket, and the arrival time of the error packet; setting the arrivaltime limit of the error packet on the basis of the reproduction time;and when the detected priority is equal to or higher than thepredetermined value and the error packet has arrived before the arrivaltime limit, outputting a retransmission request for this error packet tothe transmitting end by indicating the sequence number of this errorpacket; at the transmitting end, when data of the packet having thesequence number indicated by the retransmission request from thereceiving end is stored in the retransmission buffer, retransmittingonly data of the packet the transmission time of which does not pass thereproduction time, to the receiving end, while discarding data of thepacket the transmission time of which has passed the reproduction time;and discarding the data stored in the retransmission buffer in orderstarting from a packet which cannot be in time for reproduction at thereceiving end. Therefore, the transmission quality in a radio section inreal-time transmission is improved and, further, the number ofretransmission times is reduced.

[0029] According to a fifteenth aspect of the present invention, thedata transmission method of the fourteenth aspect, at the transmittingend, additional information relating to the sequence number, thepriority, and the reproduction time of a predetermined packet isembedded in a subsequent packet to be transmitted after thepredetermined packet; and at the receiving end, when a transmissionerror of the predetermined packet has occurred and the additionalinformation of the predetermined packet has an error, a retransmissionrequest for the predetermined packet as an error packet is made on thebasis of the additional information of the predetermined packet which isembedded in the subsequent packet, when the subsequent packettransmitted after the predetermined packet is received. Therefore, thetransmission quality in a radio section in real-time transmission isimproved and, further, the number of retransmission times is reduced.

[0030] According to a sixteenth aspect of the present invention, thedata transmission method of the fifteenth aspect, at the transmittingend, the process of embedding the sequence number a predetermined highpriority packet in a subsequent packet which follows the predeterminedhigh priority packet is continuously performed until a, high prioritypacket next to the predetermined high priority packet is transmitted;and at the receiving end, the sequence number of another packet which isembedded in the received packet is extracted, and when a transmissionerror has occurred in the packet of the extracted sequence number, aretransmission request for this packet is made by indicating thesequence number of this packet. Therefore, the transmission quality in aradio section in real-time transmission is improve and, further, thenumber of retransmission times is reduced.

[0031] According to a seventeenth aspect of the present invention in thedata transmission method of the fifteenth aspect, at the transmittingend, when additional information relating to the sequence number and thereproduction time corresponding to each packet is embedded in asubsequent packet to be transmitted after the packet; a differencebetween additional information relating to the sequence number and thereproduction time corresponding to the subsequent packet and theadditional information relating to the sequence number and thereproduction time corresponding to the previous packet is embedded asthe additional information. Therefore, the transmission quality in aradio section in real-time transmission is improved and, further, thenumber of retransmission times is reduced.

[0032] According to an eighteenth aspect of the present invention thereis provided a data transmission method for performing data transmissionbetween a distribution server and a terminal through a relay server inunits of packets, and successively reproducing data of packets receivedat the terminal. This method comprises the steps of: when a transmissionerror has occurred between the relay server and the terminal, performingretransmission of an error packet by the relay server in response to aretransmission request from the terminal; and when a transmission errorhas occurred between the distribution server and the relay server,performing retransmission of an error packet by the distribution serverin response to a retransmission request which has been transmitted fromthe terminal through the relay server. Therefore, the number ofretransmission times is reduced between the distribution server and therelay server.

[0033] According to a nineteenth aspect of the present invention, in thedata transmission method of the eighteenth aspect, when a transmissionerror has occurred between the distribution server and the relay server,a retransmission request is transmitted from the relay server to thedistribution server, and retransmission of an error packet to the relayserver is performed by the distribution server. Therefore, wastefultransmission of error packets from the relay server to the terminal isavoided.

[0034] According to a twentieth aspect of the present invention, thereis provided a data transmission apparatus for relaying data which aresuccessively transmitted from a distribution server, in units of packetseach having additional information relating to its sequence number,priority, data reproduction time at the receiving end. This apparatuscomprises: a receiving unit for receiving the packets transmitted fromthe transmitting end; a priority decision unit for deciding the priorityof each of the received packets; a retransmission packet storage unitfor storing packets the priorities of which are equal to or higher thana predetermined value, as retransmission packets, on the basis of thepriority of each packet decided by the priority decision unit; aretransmission instruction receiving unit for receiving a retransmissionrequest from a terminal at the receiving end; a retransmission decisionunit for deciding whether retransmission of the packet for which theretransmission request has been made is to be performed or not, on thebasis of the retransmission request and the storage status of theretransmission packets in the retransmission packet storage unit; aretransmission instruction output unit for outputting the retransmissionrequest for the error packet requested by the terminal, to thedistribution server, on the basis of the result of the decision in theretransmission decision unit; a transmission queue management unit forsetting the transmission order of the received packets and the packetswhich have been decided as packets to be retransmitted, on the basis ofthe additional information; and a transmission unit for transmitting thedata of these packets in the transmission order set by the managementunit. Therefore, the number of retransmission times between thedistribution server and the relay server can be reduced.

[0035] According to a twenty-first aspect of the present invention,there is provided a data transmission method for performing continuousdata transmission from the transmitting; end to the receiving end inunits of packets, each packet having additional information relating toits sequence number, priority, and data reproduction time at thereceiving end, while successively reproducing data of packets receivedat the receiving end. This method comprises the steps of: at thetransmitting end, when a packet the priority of which is equal to orhigher than a predetermined value is transmitted as a high prioritypacket, storing data of this high priority packet, as retransmissiondata, in a retransmission buffer; managing the value of the;transmitting end high priority sequence number which corresponds to thenumber of transmitted high priority packets, and the value of thesequence number of the high priority packet so that these values are;correlated with each other; and transmitting a subsequent packet whichfollows the high priority packet after embedding the value of thetransmitting end high priority sequence number in this subsequentpacket; at the receiving end, extracting the value of the transmittingend high priority sequence number which is embedded in the receivedpacket; managing the value of the receiving end high priority sequencenumber which corresponds to the number of received high prioritypackets; when the value of the extracted transmitting end high prioritysequence number is not equal to the value of the receiving end, highpriority sequence number, outputting a retransmission; request to thetransmitting end, by indicating the value of the transmitting end; highpriority sequence number which is obtained on the basis of the value ofthe receiving end high priority sequence number; and updating the valueof the receiving end high priority sequence number; at the transmittingend, only when data of the packet having the sequence numbercorresponding to the value of the transmitting end high, prioritysequence number which is indicated by the retransmission request fromthe receiving end is stored in the retransmission buffer, retransmittingthe data of this packet to the receiving end. Therefore, retransmissionof the high priority packet the priority of which is equal to or higherthan a predetermined value, can be performed by simpler procedures.

[0036] According to a twenty-second aspect of the present invention, inthe data transmission method of the twenty-first aspect, at thereceiving end, when the value of the transmitting end high prioritysequence number embedded in the received packet is not equal to thevalue of the receiving end high priority sequence number, aretransmission request is output to the transmitting end, by listing thevalues ranging from the value obtained by adding 1 to the receiving endhigh priority sequence number, to the value of the transmitting end highpriority sequence number, as the values of the transmitting end highpriority sequence numbers, or by designating the range as the range ofthe values of the transmitting end high priority sequence numbers; andat the transmitting end, the sequence numbers corresponding to thevalues of the plural transmitting end high priority sequence numberswhich are indicated by the retransmission request from the receiving endare retrieved, and only when data of the packets having the sequencenumbers obtained by the retrieval are stored in the retransmissionbuffer, the data of the packets are retransmitted to the receiving end.Therefore, retransmission of the high priority packet the priority ofwhich is equal to or higher than a predetermined value, can be performedby simpler procedures.

[0037] According to a twenty-third aspect of the present invention, inthe data transmission method of the twenty-first aspect, at thereceiving end; the retransmission request is performed continuously beseveral times, indicating the value of a transmitting end high prioritysequence number; and at the transmitting end, the sequence numb ercorresponding to the value of the transmitting end high prioritysequence number which is indicated by the retransmission request fromthe receiving end is retrieved, and also the packet having the sequencenumber obtained by the retrieval is retransmitted to the receiving endand, simultaneously, the correspondence between the value of thesequence number; obtained by the retrieval and the value of thetransmitting end high priority sequence number indicated by thereceiving end is deleted. Therefore, when at least one of severaltransmission requests from the receiving end is a normally received atthe transmitting end, only the error packet the priority of which isequal to or higher than a predetermined value can be retransmitted,whereby the transmission quality in a radio section in real-timetransmission can be effectively improved.

[0038] According to a twenty-fourth aspect of the present invention,there is provided a data transmission apparatus for relaying data whichare successively transmitted from the transmitting end in units ofpackets each packet having additional information relating to itssequence number, priority, data reproduction time at the receiving end.This apparatus comprises: a receiving unit for receiving the packetstransmitted from the transmitting end; a transmission queue managementunit for setting the transmission order of the received packets andpackets which are decided as packets to be retransmitted; a transmissionunit for transmitting data of these packets in the transmission orderset by the transmission queue management unit; a priority decision unitfor deciding the priority of each of the received packets; aretransmission packet storage unit for storing packets the priorities ofwhich are equal to or higher than a predetermined value, asretransmission packets, on the basis of the priority of each packetdecided by the priority decision unit; a sequence number management unitfor managing the value of the transmitting end high priority sequencenumber which corresponds to the number of transmitted high prioritypackets, and the value of the sequence number of the high prioritypacket so that these values are correlated with each other; a highpriority sequence number insertion unit for embedding the value of thetransmitting end high priority sequence number in a subsequent packetwhich follows thee high priority packet; a retransmission instructionreceiving unit for receiving a retransmission request indicating thehigh priority sequence number, from a terminal at the transmitting endand a retransmission decision unit for deciding whether retransmissionof the packet for which the retransmission request has been made is tobe performed or not, on the basis of the retransmission request and thestorage status of the retransmission packets in the retransmissionpacket storage unit. Therefore, only the error packet the priority ofwhich is equal to or higher than a predetermined value can beretransmitted, whereby retransmission of the high priority packet can beperformed by simpler procedures.

[0039] According to a twenty-fifth aspect of the present invention,there is provided a data receiving apparatus for receiving data whichare transmitted from the transmitting end in units of, packets, eachpacket having additional information relating to its sequence number,priority, and data reproduction time at the receiving end, andsuccessively reproducing the data for each packet. This apparatuscomprises: a receiving unit for receiving the packets transmitted fromthe transmitting end; an error packet detection unit for detecting anerror packet in which an error has occurred during transmission, andoutputting a normal packet which has been transmitted withouttransmission errors and the value of the transmitting-end high prioritysequence number which corresponds to the number of transmitted highpriority packets and is embedded in the normal packet; a high prioritysequence number management unit for managing the value of the receivingend high priority sequence number which corresponds to the number ofnormal high priority packets which have been received withouttransmission errors, on the basis of the output from the error packetdetection unit; a retransmission sequence number decision unit forcomparing the value of the transmitting end high priority sequencenumber from the error packet detection unit with the value of thereceiving end high priority sequence number, and when these values arenot equal, deciding the value of the transmitting end high prioritysequence number for which a retransmission request is to be made, on thebasis of the value of the receiving end high priority sequence number;and a retransmission instruction output unit for outputting aretransmission request to the transmitting end, by indicating the valueof the decided transmitting end high priority sequence number.Therefore, retransmission of the high priority packet can be performedwith simpler procedures.

[0040] According to a twenty-sixth aspect of the present invention,there is provided a data structure of a packet for performing datatransmission from the transmitting end and the receiving end, whereinthe packet comprises a header section containing relevant informationindicating the attribute of the packet, and a data section containingdata to be transmitted; and the header section comprises at least firstand second header information, amongst first header informationindicating the sequence number corresponding to the packet, secondheader information indicating the priority of the packet, and thirdheader information indicating the reproduction time at the receivingend, of the data to be transmitted. Therefore, retransmission of a lowpriority packet: and retransmission of a packet which cannot be in timefor reproduction can be avoided, whereby the transmission quality in aradio section in real-time transmission is improved while reducing thenumber of retransmission times.

[0041] According to a twenty-seventh aspect of the present invention, inthe packet data structure of the twenty-sixth aspect, the header sectionof the packet includes attribute information of a packet which hasalready been transmitted before the packet. Therefore, retransmission ofan error packet can be performed with reliability.

[0042] According to a twenty-eighth aspect of the present invention, inthe packet data structure of the twenty-seventh aspect, the headersection of the packet includes the first and second information or thefirst and third information, as attribute information of a packet whichhas already been transmitted before the packet. Therefore,retransmission control based on the priority or the reproduction timecan be performed with reliability.

[0043] According to a twenty-ninth aspect of the present invention, inthe packet data structure of the twenty-sixth aspect, the header sectionof the packet includes the value of the high priority sequence; numbercorresponding to the number of high priority packets which have beentransmitted before the packet and having the priorities equal to orhigher than a predetermined value. Therefore, the transmission qualityin a radio section in real-time transmission is improved and, moreover,retransmission of an error packet is realized by simpler procedures.

BRIEF DESCRIPTION OF THE DRAWINGS

[0044] FIGS. 1(a) and 1(b) are block diagrams for explaining datatransmission apparatuses as a relay server and a distribution server,respectively, in a data transmission system according to a firstembodiment of the present invention.

[0045]FIG. 2 is a block diagram illustrating a data receiving apparatus(receiving terminal) in the data transmission system according to thefirst embodiment.

[0046]FIG. 3 is a sequence diagram for explaining packet selectiveretransmission control in a data transmission method according to thefirst embodiment.

[0047]FIG. 4 is a block diagram illustrating a data transmissionapparatus (relay server) in a data transmission system according to asecond embodiment of the present invention.

[0048]FIG. 5 is a block diagram illustrating a data receiving apparatus(receiving terminal) in the data transmission system according to thesecond embodiment.

[0049]FIG. 6 is a sequence diagram for explaining packet selectiveretransmission control in a data transmission method according to athird embodiment of the present invention.

[0050]FIG. 7 is a block diagram illustrating a data transmissionapparatus (relay server) in a data transmission system according to amodification of the third embodiment.

[0051]FIG. 8 is a block diagram illustrating a data receiving apparatus(receiving terminal) in the data transmission system according to themodification of the third embodiment.

[0052]FIG. 9 is a sequence diagram for explaining packet selectiveretransmission control in a data transmission method according to themodification of the third embodiment.

[0053]FIG. 10 is a block diagram illustrating a data transmissionapparatus (relay server) in a data transmission system according to afourth embodiment of the present invention.

[0054]FIG. 11 is a block diagram illustrating a data receiving apparatus(receiving terminal) in the data transmission system according to thefourth embodiment.

[0055]FIG. 12 is a sequence diagram for explaining a first example ofpacket selective retransmission control in a data transmission methodaccording to the fourth embodiment.

[0056]FIG. 13 is a sequence diagram for explaining a second example ofpacket selective retransmission control in the data transmission methodaccording to the fourth embodiment.

[0057]FIG. 14 is a sequence diagram for explaining a third example ofpacket selective retransmission control in the data transmission methodaccording to the fourth embodiment.

[0058]FIG. 15 is a sequence diagram for explaining a fourth example ofpacket selective retransmission control in a data transmission methodaccording to a modification of the fourth embodiment.

[0059] FIGS. 16(a) and 16(b) are block diagrams for explaining a datatransmission apparatus as a relay server and a data receiving apparatusas a receiving terminal, respectively, in a data transmission systemaccording to a fifth embodiment of the present invention.

[0060]FIG. 17 is a sequence diagram for explaining packet selectiveretransmission control in a data transmission method according to thefifth embodiment.

[0061]FIG. 18 is a block diagram illustrating a data transmissionapparatus (relay server) in a data transmission system according to asixth embodiment of the present invention.

[0062]FIG. 19 is a block diagram illustrating a data receiving apparatus(receiving terminal) in the data transmission system according to thesixth embodiment.

[0063]FIG. 20 is a sequence diagram for explaining packet retransmissioncontrol with time limit, in the data transmission method according tothe sixth embodiment.

[0064]FIG. 21 is a sequence diagram for explaining packet retransmissioncontrol with time limit, in a data transmission method according to anmodification of the sixth embodiment.

[0065]FIG. 22 is a sequence diagram for explaining packet retransmissioncontrol with time limit, in a data transmission method according toanother modification of the sixth embodiment.

[0066]FIG. 23 is a block diagram illustrating a data transmissionapparatus (relay server) in a data transmission system according to aseventh embodiment of the present invention.

[0067]FIG. 24 is a block diagram illustrating a data transmissionapparatus (relay server) in a data transmission system according to amodification of the seventh embodiment.

[0068]FIG. 25 is a block diagram illustrating a data transmissionapparatus (relay server) in a data transmission system according to aneighth embodiment of the present invention.

[0069]FIG. 26 is a block diagram illustrating a data receiving apparatus(receiving terminal) in the data transmission system according to theeighth embodiment.

[0070] FIGS. 27(a) and 27(b) are diagrams for explaining a reproductiontime estimation method according to the eighth embodiment illustratingthe relationship between the time stamp of a packet and the packetoutput time (FIG. 27(a)) and a time stamp mapping method (FIG. 27(b)).

[0071] FIGS. 28(a) and 28(b) are schematic diagrams for conceptuallyexplaining the conventional video transmission system, illustrating aserver and a terminal connected by a cable (FIG. 28(a)), and a serverand a terminal connected by a network including a radio transmissionsection.

[0072] FIGS. 29(a) and 29(b) are block diagrams for explaining a datatransmission apparatus as a relay server and a data transmissionapparatus as a distribution server, respectively, in a data transmissionsystem according to a ninth embodiment of the present invention.

[0073]FIG. 30 is a block diagram illustrating a data receiving apparatus(receiving terminal) in the data transmission system according to theninth embodiment.

[0074]FIG. 31 is a sequence diagram for explaining packet selectiveretransmission control in the real-time data transmission methodaccording to the ninth embodiment.

[0075]FIG. 32 is a block diagram illustrating a data transmissionapparatus (relay server) in a data transmission system according to atenth embodiment of the present invention.

[0076]FIG. 33 is a block diagram illustrating a data receiving apparatus(receiving terminal) in the data transmission system according to thetenth embodiment.

[0077] FIGS. 34(a)-34(c) are diagrams illustrating the data structure ofa packet for transmitting data by a data transmission method accordingto any of the aforementioned embodiments (FIG. 34(a)), the structure ofthe packet header (FIG. 34(b)), and the convention of header information(FIG. 34(c)).

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0078] Hereinafter, the inventor's viewpoint and the fundamentalprinciple of the present invention will be described.

[0079] The inventors of the present invention have earnestly studiedabout a method for improving the transmission quality in a networkincluding a radio transmission section, and finally discovered that thetransmission quality in the radio section can be improved by performingreal-time retransmission of packets, in the existing real-timetransmission method.

[0080] To be specific, in the existing real-time transmission method,packet data are transmitted in real time between a distribution serverand a terminal unit through a relay server or the like, and additionalinformation (e.g., a sequence number, a time stamp, etc) required forreal-time transmission of each packet data is given to the header of thepacket. The additional information enables real-time control of packetretransmission.

[0081] In the data transmission method of the present invention in whichdata transmission is performed in real time between the distributionserver and the terminal through the relay server while retransmissioncontrol is performed in real time, the relay server may serve as thevideo distribution server. Further, as for the video data transmissiondirection, the present invention can be applied to not only the forwardtransmission from the distribution server to the terminal but also thebackward transmission from the terminal to the distribution server.

[0082] Further, in the present invention, for effective real-timetransmission, control of transmission QoS (Quality of Service) in therelay server is realized.

[0083] Next, the summary of real-time retransmission control in the datatransmission method of the present invention will be briefly described.

[0084] While the real-time retransmission control of the presentinvention regards the transmission quality of the radio section andrecovers error packets due to radio transmission error by retransmissionof the packets, the conventional retransmission control is directed torealize high reliability in data transmission (error-free transmission).That is, in order to recover all error packets, retransmission of errorpackets is repeated until data are correctly transmitted to thereceiving end. In the conventional retransmission control when the finalerror packet retransmission has failed, the data transmission isabnormally ended as a communication error.

[0085] By the way, in the retransmission control required for thereal-time video data transmission, even when a transmission error occurswhile predetermined packets are transmitted and thereby, several framesof images are lost, this is not a fatal transmission error which leadsto abnormal end of data transmission. Accordingly, in the video datatransmission method, to complete real-time transmission with a measureof reliability is given the highest priority.

[0086] For example, in transmission of a video signal based on MPEGstandard, in the case where a packet corresponding to an I frame(intra-frame coded image) as a reference image becomes an error packet,even when subsequent packets corresponding to a P frame (inter-frameforward-prediction coded image) and a B frame (inter-framebidirectional-prediction coded image) are received normally, videosignals of the P frame and the B frame cannot be reproduced. So, as forthe I frame, it is necessary to recover the transmission error to theutmost.

[0087] Further, in video transmission (stream type communication havingan audio signal and a video signal as objects to be transmitted), incontrast with the conventional retransmission control, it is necessaryto perform retransmission while performing real-time transmission.

[0088] In order to realize such real-time transmission, the presentinvention provides a real-time transmission method in which thefollowing retransmission control for error packets is performed.

[0089] First retransmission control is selective retransmission controlfor reducing the number of retransmission times by selecting, as packetsto be retransmitted, high priority packets amongst the error packets.Second retransmission control is retransmission control with time limitfor reducing excessive retransmission by stopping retransmission ofpackets which cannot be in time for reproduction, amongst the errorpackets.

[0090] Hereinafter, embodiments of the present invention will bedescribed.

[0091] [Embodiment 1]

[0092] FIGS. 1-3 are diagrams for explaining a data transmission methodaccording to a first embodiment of the present invention.

[0093] In the data transmission method of this first embodiment, datatransmission from the transmitting end to the receiving end iscontinuously performed in units of packets, each packet havingadditional information relating to its sequence number, priority, anddata reproduction time at the receiving end, while successivelyreproducing data of packets received at the receiving end. At this time,only error packets the priorities of which are equal to or higher than apredetermined value are retransmitted.

[0094]FIG. 1(a) is a block diagram illustrating a data transmissionapparatus 101 in a data transmission system which performs real-timedata transmission according to the data transmission method of the firstembodiment.

[0095] This data transmission apparatus 101 constitutes a relay server(transmitting end) which relays data transmitted between a distributionserver and a terminal (receiving end). This apparatus 101 includes areceiving unit 11, a transmission queue management unit 12, and atransmission unit 13. The receiving unit 11 receives packets transmittedfrom the distribution server. The transmission queue management unit 12sets the transmission order of the received packets and the packets tobe retransmitted (hereinafter referred to as retransmission packets) inaccordance with the above-described additional information. Thetransmission unit 13 transmits the packet data in the transmission orderwhich has been set by the transmission queue management unit 12.

[0096] Each packet transmitted from the transmitting end is composed ofa data section containing digital data such as video data, audio data,and text data, and a header section containing additional informationother than these digital data. To be specific, the header section ofeach packet contains additional information relating to its sequencenumber, priority, and data reproduction time at the receiving end.

[0097] Further, the data transmission apparatus 101 includes a buffer 17for retransmission (hereinafter, referred to as a retransmission buffer17), a packet priority decision unit 15, and a retransmission buffermanagement unit 18. The retransmission buffer 17 stores predeterminedpackets amongst the received packets, as retransmission packets. Thepacket priority decision unit 15 decides the priorities of the receivedpackets. The retransmission buffer management unit 18 controls theretransmission buffer 17 such that data of packets the priorities ofwhich are equal to or higher than a predetermined value are stored inthe buffer 17, in accordance with the decided priorities of the packets.To be specific, only when data of a packet having a sequence numberindicated by a retransmission request from the receiving side is storedin the retransmission buffer 17, the retransmission decision unit 16decides that data of this packet should be retransmitted to thereceiving end.

[0098] Further, the data transmission apparatus 101 includes aretransmission instruction receiving unit 14 and a retransmissiondecision unit 16. The retransmission instruction receiving unit 14receives a retransmission instruction (hereinafter also referred to as aretransmission request) from the terminal at the receiving end. Theretransmission decision unit 16 decides whether retransmission of apacket for which the retransmission instruction has been made isperformed or not.

[0099] While in FIG. 1(a) the data transmission apparatus 101constitutes a relay server, when the data transmission apparatus is adistribution server, it is constructed as shown in FIG. 1(b). That is,in FIG. 1(b), the receiving unit 11 of the data transmission apparatus101 is replaced with a coded packet generation unit, 10 a which encodesthe data and outputs the coded data in packet units, and a priorityallocation unit 10 b which allocates additional information such as apriority to each packet output from the coded packet generation unit 10a.

[0100]FIG. 2 is a block diagram illustrating a data receiving apparatus201 in the data transmission system which performs real-time datatransmission according to the data transmission method of the firstembodiment.

[0101] The data receiving apparatus 201 includes a receiving unit 21, anerror packet detection unit 22, and a packet decoding unit 23. Thereceiving unit 21 receives the packets transmitted from the relay server(the data transmission apparatus at the transmitting end). The errorpacket detection unit 22 detects error packets in which errors haveoccurred during transmission, and outputs normal packets which have beentransmitted without transmission errors. The packet decoding unit 23receives the normal packets and decodes the coded data of the normalpackets.

[0102] Further, the data receiving apparatus 201 includes a receptionhistory management unit 24, a packet priority decision unit 25, and aretransmission instruction output unit 26. The reception historymanagement unit 24 manages the packet reception history. The packetpriority decision unit 25 receives the result of the detection in theerror packet detection unit 22 and decides an error packet the priorityof which is equal to or higher than a predetermined value. Theretransmission instruction output unit 26 outputs a request forretransmitting the error packet which has been decided in the packetpriority decision unit 25, toward the transmitting end, by indicatingthe sequence number of the error packet.

[0103] Next, the function, and effect will be described.

[0104]FIG. 3 is a sequence chart for explaining the packet selectiveretransmission control in the data transmission method of the firstembodiment.

[0105] In the data transmission method of this first embodiment, when antransmission error occurs during packet transmission, a retransmissionrequest is made for only the packets the priorities of which are equalto or higher than a predetermined value, from the receiving end to thetransmitting end, while no retransmission request is made for the errorpackets the priorities of which are lower than the predetermined value.

[0106] For example, assuming that the priorities equal to or higher thanthe predetermined value are high priorities while the priorities lowerthan the predetermined value are low priorities, when an error occursduring transmission of a high priority packet (S1) of sequence number,S1, a retransmission request for this high priority packet (S1) is made.However, when an error occurs during transmission of a low prioritypacket (S2) of sequence number S2, no retransmission request is made forthis low priority packet (S2).

[0107] To be specific, each packet transmitted from the distributionserver is given additional information relating to its sequence numberand priority. In the data transmission apparatus 101 as a relay server,the transmission order of the received packets is set by thetransmission queue management unit 12, and the packets are supplied tothe transmission unit 13. On the other hand, the priorities of thereceived packets are decided by the packet priority decision unit 15.Then, in the transmission unit 13, transmission of these packets isperformed according to the transmission order, which has been set.Further, those packets the priorities of which are decided as beingequal to or higher than the; predetermined value are stored in theretransmission buffer 17 under control of the retransmission buffermanagement unit 17. Further, in the retransmission buffer 17, data aresuccessively released (discarded) from the packets which cannot be intime for reproduction, under control of the management unit 18.

[0108] When the retransmission buffer 17 has no more vacant space(capacity), one of the following two processes is performed a firstupdation process in which the above-described retransmission data isretained while the data of the packets stored in the retransmissionbuffer 17 are discarded in order starting from a packet of the earliestreproduction time; and a second updation process in which theretransmission data is retained while successively discarding the datastored in the retransmission buffer 17 so that reproduction of packetdata for predetermined packets, amongst the packet of the earliestreproduction time and the subsequent packets, is performed at regularintervals at the receiving end.

[0109] In this way, the packets from the distribution server aresuccessively transmitted to the terminal (data receiving apparatus) 201through the relay server (data transmission apparatus) 101.

[0110] In the data receiving apparatus 201, the packets from the relayserver (data transmission apparatus) 101 are received by the receivingunit 21, and the received packets are supplied to the error packetdetection unit 22. Then, only the packets, which have been transmittedwithout transmission errors are output from the error packet detectionunit 22 to the packet decoding unit 23, and the additional informationof each packet is supplied to the reception history management unit 24.At this time, the priority information of each error packet is suppliedto the packet priority decision unit 25, wherein it is decided whetheror not the priority of the error packet is equal to or higher than apredetermined value. With respect to the error packet the priority ofwhich is equal to or higher than the predetermined value, theretransmission instruction output unit 26 outputs a retransmissionrequest to the transmitting end, by indicating the sequence number ofthis error packet.

[0111] Then, in the data transmission apparatus 101 at the transmittingend, the retransmission request is received by the retransmissioninstruction receiving unit 14, and it is decided by the retransmissiondecision unit 16 as to whether the packet of the sequence numberindicated by the retransmission request is stored in the retransmissionbuffer 17 or not. When the packet of the sequence number indicated bythe retransmission request is stored in the retransmission buffer 17,this packet is output as a retransmission packet, from theretransmission buffer 17 to the transmission queue management unit 12.In the transmission queue management unit 12, the retransmission packetis given a predetermined transmission order and then retransmitted tothe receiving end through the transmission unit 13.

[0112] As described above, according to the first embodiment of thepresent invention, data transmission from the transmitting end to thereceiving end 1 s continuously performed in units of packets each havingadditional information relating to its sequence number, priority, anddata reproduction time and, simultaneously, data of the packets receivedat the receiving end are successively reproduced. With respect to errorpackets affected by transmission errors, only those having prioritiesequal to or higher than a predetermined value are retransmitted.Therefore, the transmission quality of the radio section in thereal-time transmission is improved and, moreover, the number ofretransmission times can be reduced.

[0113] In this first embodiment, each packet may be given the frametype, such as I frame, P frame, and B frame, as the additionalinformation, instead of the priority.

[0114] Further, there are various methods for deciding the packetpriority. For example, in the case of a video signal based on the MPEGstandard, packets corresponding to I frames may be decided as highpriority packets. Further, in the packet discarding process performedwhen the retransmission buffer is filled to the capacity, theabove-described first or second updation process may be performed on thepackets in the order of ascending priorities.

[0115] [Embodiment 2]

[0116] FIGS. 4-5 are diagrams for explaining a data transmission methodaccording to a second embodiment of the present invention.

[0117]FIG. 4 is a block diagram illustrating a data transmissionapparatus 102 in a data transmission system which performs real-timedata transmission according to this data transmission method.

[0118] The data transmission apparatus 102 includes an error correctionunit 31, in addition to the constituents of the data transmissionapparatus 101 of the first embodiment. The error correction unit 31performs an error correction process in which each packet output fromthe transmission queue management unit 12 is given error correctioncodes for additional information such as its sequence number priority,etc., and the packet which has been subjected to the error correctionprocess is supplied to the transmission unit 13. Other constituents ofthe data transmission apparatus 102 are identical to those of the datatransmission apparatus 10; of the first embodiment.

[0119]FIG. 5 is a block diagram illustrating a data receiving apparatus202 in the data transmission system which performs the real-time datatransmission according to the data transmission method of this secondembodiment.

[0120] The data receiving apparatus 202 of this second embodimentincludes an error correction unit 41, in addition to the constituents ofthe data receiving apparatus 201 of the first embodiment. The errorcorrection unit 41 performs an error correction process in which eachpacket received by the receiving unit 21 is subjected to an errorcorrection process in which the additional information of this packet issubjected to error correction by using the error correction codes givento the packet, and the packet which has been subjected to the errorcorrection process is output to the error packet detection unit 22.Other constituents of the data receiving apparatus 202 are identical tothose of the data receiving apparatus 201 of the first embodiment.

[0121] Next, the function and effect will be described.

[0122] In the data transmission method according to the secondembodiment, at the transmitting end, each packet to be transmitted isgiven error correction codes for the additional information relating toits sequence number, priority, etc. At the receiving end, the additionalinformation is subjected to error correction according to the errorcorrection codes and, thereafter, a retransmission request for the errorpacket is made in accordance with the additional information. Thereby,even when the sequence number and the priority information have errors,a retransmission request for the error packet can be correctlyperformed.

[0123] [Embodiment 3]

[0124] FIGS. 6-9 are diagrams for explaining data transmission methodsaccording to a third embodiment of the invention and a modification ofthe, third embodiment. FIG. 6 is a sequence diagram for explainingpacket selective retransmission control in the data transmission methodof the third embodiment.

[0125] In the data transmission method of the third embodiment, at thetransmitting end, additional information relating to the sequence numberand priority of a predetermined packet is embedded in a subsequentpacket which will be transmitted after the predetermined packet. At thereceiving end, when a transmission error of the predetermined packetoccurs and thereby the additional information of the predeterminedpacket has, an error, a retransmission request for the error packet ismade when receiving the subsequent packet which is transmitted after theerror packet, in accordance with the additional information of thepredetermined packet which is embedded in the subsequent packet.

[0126] For example, assuming that the priorities equal to or higher thana predetermined value are high priorities while the priorities lowerthan the predetermined value are low priorities, as shown in FIG. 6,when an error occurs during transmission of a high priority packet (S1)of sequence number S1 and only a low priority packet (S2) of sequencenumber S2 which follows the packet S1 is normally received, aretransmission request for the high priority packet (S1), is made whenthe next low priority packet (S2) is received.

[0127] On the other hand, when an error occurs during transmission of alow priority packet (S3) of sequence number S3 and only a high prioritypacket (S4) of sequence number S4 which follows the packet S3 isnormally received, no retransmission request for the low priority packetS3 is made when the next high priority packet (S4) is received.

[0128] In the data transmission method so constructed, even when anerror occurs during transmission of a predetermined packet and therebythe sequence number or the priority information of this packet has anerror, since the additional information (sequence number, priority,etc.) of the predetermined packet is embedded in the subsequent packetwhich is transmitted next to this packet, a transmission request forthis error packet (predetermined packet) can be made correctly.

[0129] While in this third embodiment the additional information of eachpacket is embedded in the next packet, it may be embedded in, not onlythe next packet, but, also a plurality of subsequent packets. Thisconstruction will be described hereinafter as a modification of thethird embodiment.

[0130] [‘Modification’ of Embodiment 3]

[0131]FIG. 7 is a block diagram illustrating a data transmissionapparatus 103 in a data transmission system which performs real-timedata transmission by using a data transmission method according to themodification of the third embodiment.

[0132] The data transmission apparatus 103 includes a sequence numberstorage unit 33 and a sequence number insertion unit 32, in addition tothe constituents of the data transmission apparatus 101 of the firstembodiment. The sequence number storage unit 33 stores the sequencenumbers of the packets the priorities of which are equal to or higherthan a predetermined value, amongst the packets transmitted by atransmission unit 13 a. The sequence number insertion unit 32 outputseach of the sequence numbers stored in the sequence number storage unit33 to the transmission unit 13 a so that the sequence number is insertedin the header of the packet to be transmitted. Further, the transmissionunit 13 a of this modification is different from the transmission, unit13 of the first embodiment only in that it inserts the sequence numbersupplied from the sequence number insertion unit 32 into the header ofthe packet supplied from the transmission queue management unit 12,before transmitting the packet. Other constituents of the datatransmission apparatus 103 are identical to those of the, datatransmission apparatus 101 of the first embodiment.

[0133]FIG. 8 is a block diagram illustrating a data receiving apparatus203 in the data transmission system which performs the read-time datatransmission by using the data transmission method according to themodification of the third embodiment.

[0134] The data receiving apparatus 203 according to the modification ofthe third embodiment includes an inserted sequence extraction unit 42,in addition to the constituents of the data receiving apparatus 201 ofthe first embodiment. The inserted sequence, extraction unit 42extracts, from a normal packet output from the error packet detectionunit 22, the sequence number of a high priority packet which has beenreceived in advance of the normal packet. The normal packet is output tothe packet decoding unit 23 through the inserted sequence extractionunit 42. Further, in the data receiving apparatus 203, the packetpriority decision unit 25 a outputs a retransmission request to theretransmission instruction output unit 26 when the packet of thesequence number extracted by the inserted sequence extraction unit 42 isan error packet. Other constituents of the data receiving unit 203 areidentical to those of the data receiving apparatus 201 of the firstembodiment.

[0135] Next, the function and effect will be described.

[0136]FIG. 9 is a sequence diagram for explaining packet selectiveretransmission control in the data transmission method according to themodification of the third embodiment.

[0137] In the data transmission apparatus (transmitting end) 103, inaddition to the transmission operation of the data transmissionapparatus 101 according to the first embodiment, the process ofembedding the sequence number of a high priority packet to betransmitted in the subsequent packets, is carried out until the nexthigh priority is transmitted.

[0138] For example, assuming that the priorities equal to or higher thana predetermined value are high priorities while the priorities lowerthan the predetermined value are low priorities, as shown in FIG. 9,after a high priority packet (S1) of sequence number S1, has beentransmitted; subsequent packets (S2)˜(S4) of sequence numbers S2˜S4 aretransmitted after the sequence number S1 of the previous high prioritypacket (S1) is embedded therein, and then a high priority packet (S5) ofsequence number S5 is transmitted after the sequence number S4 of theprevious high priority packet (S4) is embedded therein.

[0139] When an error occurs while the high priority packet (S1) and thesubsequent low priority packets (S2) and (S3) are transmitted and soonly the high priority packet (S4) is normally received, aretransmission request for the first high priority packet S1 is madewhen the next high priority packet (S4) is received.

[0140] Further, in the data receiving apparatus (receiving end) 203, inaddition to the receiving operation of the data receiving apparatus 201of the first embodiment, the following retransmission is performed. Thatis, when the sequence number embedded in the received packet isextracted, if the packet corresponding to this sequence number is anerror packet, a packet retransmission request is sent to thetransmitting end by using the sequence number of this packet.

[0141] In the data transmission method according to the modification ofthe third embodiment, at the transmitting end, the process of embeddingthe sequence number of a high priority packet, the priority of which isequal to or higher than a predetermined value, into the subsequentpackets which follow this high priority packet, is continued until ahigh priority packet next to the high priority packet is transmitted. Atthe receiving end, the, sequence number of another packet (high prioritypacket) embedded in the received packet is extracted. When this packet(another packet) is an error packet, a retransmission request for thispacket is made by indicating the sequence number of: this packet.Therefore, even when two successive packets become error packets, thesequence number of the high priority packet which has become an errorpacket can be detected from the header information of the subsequentpacket which is transmitted without a transmission error, whereby aretransmission request for the high priority error packet can be madewith higher reliability.

[0142] In the third embodiment, the sequence number and priorityinformation of each packet are embedded in the header of a packet to betransmitted next to this packet, and in the modification of the thirdembodiment, the sequence number of a high priority packet to betransmitted is embedded in the subsequent plural packets until the nexthigh priority packet is transmitted. However, the information to beembedded in the subsequent packet is not restricted thereto. Forexample, the number of retransmission times may be embedded in thesubsequent packet together with the sequence number.

[0143] In this case, at the transmitting end, information relating tothe number of retransmission times is embedded in each packet togetherwith the sequence number. At the receiving end, when making aretransmission request for an error packet, the number of retransmissiontimes and the sequence number corresponding to the error packet arepaired and indicated to the transmitting end. At the transmitting end, aselective retransmission process is performed as follows. That is,retransmission of the error packet for which the retransmission requesthas been made is performed when the data of the packet having thesequence number indicated by the retransmission request from thereceiving end is stored in the retransmission buffer and there ismatching in the number of retransmission times between the packet forwhich the retransmission request is made and the packet which is storedin the buffer and has the identical sequence number. Then, the number ofretransmission times of the retransmitted packet in the retransmissionbuffer is incremented.

[0144] Hereinafter, a specific construction for embedding the number ofretransmission times (hereinafter also referred to as retransmissioncount) in the subsequent packets will be described as a fourthembodiment of the invention.

[0145] [Embodiment 4]

[0146] FIGS. 10-15 are diagrams for explaining a data transmissionmethod according to a fourth embodiment of the present invention.

[0147]FIG. 10 is a block diagram illustrating a data transmissionapparatus 104 in a data transmission system which performs real-timedata transmission by the data transmission method according to thefourth embodiment.

[0148] The data transmission apparatus 104 includes a sequencenumber/retransmission count storage unit 35, a sequencenumber/retransmission count insertion unit 34, and a retransmissioncount clear unit 38. The sequence number/retransmission count storageunit 35 stores the sequence numbers and the retransmission counts, ofthe packets the priorities of which are equal to or higher than apredetermined value, amongst the packets transmitted by the transmissionunit 13 a. The sequence number/retransmission count insertion unit 34outputs the sequence number and the retransmission count which arestored in the storage unit 35, to the transmission unit 13 a, such thatthese data are inserted in the header of the packet to be transmitted.The retransmission count clear unit 38 subjects the packet received atthe receiving unit 11 to a process of clearing the retransmission count,and outputs the packet to the transmission queue management unit 12.Further, the transmission unit 13 a of this fourth embodiment isdifferent in function from the transmission unit 13 of the firstembodiment only in that it inserts the sequence number and theretransmission count supplied from the sequence number/retransmissioncount insertion unit 34 into the header of the packet supplied from thetransmission queue management unit 12 and then transmits this packet.

[0149] The data transmission apparatus 104 further includes a sequencenumber/retransmission count comparison unit 36 which receives theretransmission-instruction received by the retransmission instructionreceiving unit 14 (i.e., the sequence number and retransmission count ofthe packet to be retransmitted) through the reproduction decision unit16 a, and compares the sequence number of the packet for which theretransmission request, has been made with the sequence numbers of thepackets stored in the retransmission buffer 17. Further, it compares theretransmission count of the packet for which the retransmission requesthas been made with the retransmission count of the packet which isstored in the retransmission buffer 17 and has the sequence numberindicated by the retransmission request.

[0150] In the data transmission apparatus 104, the retransmissiondecision unit 16 a decides retransmission of packets as follows, inaccordance with the output from the comparison unit 36. To be specific,when the sequence number of the rearmost packet which has been receivedmost recently is larger than the sequence number of the error packet, itis decided that selective retransmission should be performed on theerror packet. On the other hand, when the sequence number of therearmost packet is smaller than the sequence number of the error packet,it is decided that selective retransmission should be performed on apacket having a sequence number which is larger than the sequence numberof the rearmost packet and equal to or smaller than the sequence numberof the error packet. Further, the retransmission buffer 17 a outputs thepacket to be retransmitted, to the transmission queue management unit12, in accordance with the result of the decision in the retransmissionpropriety decision unit 16 a.

[0151] In FIG. 10, the sequence number/retransmission count incrementunit increments the retransmission count (number of retransmissiontimes) of the packet in the retransmission buffer 17 a, which packet isdecided to be retransmitted by the retransmission decision unit 16 a.

[0152] Other constituents of the data transmission apparatus 104 areidentical to those of the data transmission apparatus of the firstembodiment.

[0153]FIG. 11 is a block diagram illustrating a data receiving apparatus204 in the data transmission system which performs the real-time datatransmission according to the data transmission method of the fourthembodiment.

[0154] The data receiving unit 204 of this fourth embodiment includes aretransmission instruction output unit 26 a, instead of theretransmission instruction output unit 26 of the data receivingapparatus 203 according to the modification of the third embodiment. Theretransmission instruction output unit 206 a outputs a retransmissioninstruction which requests retransmission of a packet, by usinginformation in which the sequence number and retransmission count ofthis packet are paired.

[0155] Other constituents of the data receiving apparatus 204 areidentical to those of the data receiving apparatus 203 according to themodification of the third embodiment.

[0156] Next, the function and effect will be described.

[0157]FIG. 12 a sequence diagram for explaining packet selectiveretransmission control in the data transmission method of the fourthembodiment, illustrating a first example of data exchange between thetransmitting end and the receiving end.

[0158] In the state shown in FIG. 12, the high priority packet ofsequence number S1 has already been received normally at the receivingend. Hereinafter, a packet having a sequence number Sn andretransmission count N is represented as a packet (Sn,N): [n,N: naturalnumbers]. In the figure, packets of sequence numbers S1, S2, and S4 arehigh priority packets, and packets of sequence numbers, S3 and S5 arepackets other than the high priority packets. In this fourth embodiment,only the additional information of the above-mentioned high prioritypackets are embedded in the subsequent packets.

[0159] Initially, as shown in FIG. 12, at a predetermined transmissiontiming, the high priority packet (S2,1) subsequent to the high prioritypacket (S1) is retransmitted. At this time, in the header of the packet(S2,1), the sequence number S1 and retransmission count of the highpriority packet (S1) are embedded as well as its sequence number S2 andretransmission count 1.

[0160] At the next transmission timing, the packet (S3) subsequent tothe high priority packet (S2,1) is transmitted having, in its header,the sequence number S2 and retransmission count 1 of the high prioritypacket (S2,1) as well as its sequence number S3.

[0161] At the next transmission timing, the next high priority packet(S4,1) is retransmitted, having, in its header, the sequence number S2and retransmission count 1 of the high priority packet (S2,1) as well asits sequence number S4 and retransmission count 1.

[0162] At the next transmission timing, the next packet (S5) istransmitted, having, in its header, the sequence number S4 andretransmission count 1 of the high priority packet (S4,1) as well as itssequence number S5.

[0163] In the above-described four times of packet transmission,transmission error has occurred during the first to third packettransmission and, therefore, the packets (S2,1), (S3), and (S4) are notreceived at the receiving end while only the packet (S5 is received.

[0164] In this state, at the transmitting end, it is known that the highpriority packet which has been received most recently is the packethaving the sequence number S1, and the error packet is the packet havingthe sequence number S4 and the retransmission count 1, but it is notknown what kinds of packets have been transmitted between the highpriority packet (S1) and the packet (S5).

[0165] So, the receiving end sends a retransmission request for the highpriority packet (S4,1), together with the sequence number of themost-recently received high priority packet as well as the sequencenumber S4 and retransmission count 1 of this packet (S4,1).

[0166] Then, at the transmitting end, the sequence number S1 of mostrecently received high priority packet is compared with the sequencenumber S4 of the error packet for which the retransmission request hasbeen made. In this case, since the sequence number of the most-recentlyreceived high priority packet is smaller than the sequence number of theerror packet, the transmitting end performs selective retransmission forthose packets having sequence numbers larger than the sequence number S1and equal to or smaller than the sequence number S4.

[0167] In this case, the high priority packet (S2,2) is transmittedhaving, in its header, the sequence number S4 and retransmission count 1of the high priority packet (S4,1) and, subsequently, the high prioritypacket (S4,2) is transmitted, having, in its header the sequence numberS2 and retransmission count 2 of the high priority packet (S2,2).

[0168] On receipt of the high priority packet (S2,2), the receiving endsends a retransmission request for the high priority packet (S4,1)toward the transmitting end, together with the sequence number S2 of themost-recently received high priority packet (S2,2) as well as thesequence number S4 and retransmission count 1 of this packet (S4,1).However, with respect to the high priority packet (S4), since the secondretransmission has already been done, no retransmission is performed inresponse to the retransmission request for the high priority packet(S4,1).

[0169] Next, another example of data exchange will be described by usinga sequence diagram of FIG. 13.

[0170] In the case shown in FIG. 13, data exchange from transmission ofthe high priority packet (S2,1) to transmission of the high prioritypacket (S2,2) is identical to that describe with respect to FIG. 12.

[0171] In the case shown in FIG. 13, transmission of the high prioritypacket (S2,2) is error transmission, and the next high priority packet(S4,2) is normally received.

[0172] In this case, at the receiving end, it is known that the highpriority packet which has been received most recently has the sequencenumber S4, and the error packet has the sequence number S2 and theretransmission count 2.

[0173] So, the receiving end sends a retransmission request for the highpriority packet (S2,2), together with the sequence number S4 of the mostrecently received high priority packet as well as the sequence number S2and retransmission count 2 of this packet (S2,2).

[0174] Then, at the transmitting end, the sequence number S4 of themost-recently received high priority packet is compared with thesequence number S2 of the error packet for which the retransmissionrequest has been made. In this case, since the sequence number S4 of themost recently received high priority packet is larger than the sequencenumber S2 of the error packets the transmitting end performs selectiveretransmission for only the error packet.

[0175] That is, the high priority packet (S2,3) is transmitted, having,in its header, the sequence number S4 and retransmission count 2 of thehigh priority packet (S4,2).

[0176] Next, still another example of data exchange will be described byusing a sequence diagram of FIG. 14.

[0177] Initially, as shown in FIG. 14, at a predetermined transmissiontiming, the high priority packet (S4,1) is retransmitted, having, in itsheader, the, sequence number S2 and retransmission count 1 of the highpriority packet (S2,1) which has been transmitted in advance of thispacket, as well as the sequence number S4 and retransmission count 1 ofthis packet.

[0178] At the next transmission timing, the next packet (S5) istransmitted, having, in its header, the sequence number 54 andretransmission count 1 of the high priority packet (S4,1) as well as thesequence number S5 of this packet.

[0179] In this example, a transmission error has occurred during thefirst packet transmission, and so the packet (S4,1) is not been receivedat the receiving end while only the packet (S5) is received.

[0180] In this state, at the receiving end, it is known that themost-recently received, high priority packet has the sequence number S1,and the error packet has the sequence number S4 and the retransmissioncount 1.

[0181] So, the receiving end sends a retransmission request for the highpriority packet (S4,1), together with the sequence number S1 of themost-recently received high priority packet as well as the sequencenumber S4 and retransmission count 1 of this packet.

[0182] Then, at the transmitting end, the sequence number S1 of themost-recently received high priority packet is compared with thesequence number S4 of the error packet for which the retransmissionrequest has been made. In this case, since the sequence number S1 of themost-recently received high priority packet is smaller than the sequencenumber S4 of the error packet the transmitting end performs selectiveretransmission for those packets having sequence numbers larger than thesequence number S1 and equal to or smaller than the sequence number S4.

[0183] In this cease, the high priority packet (S2,2) is transmittedhaving, in its header; the sequence number S4 and retransmission count 1of the high priority packet (S4,1) as well as the sequence number S2 andretransmission count Z of this packet (S2,2) and, subsequently, the highpriority packet (S4,2) is transmitted, having, in its header, thesequence number S2 and retransmission count 2 of the high prioritypacket (S2,2) as well as the sequence number S4 and transmission count 2of this packet. Thereafter, the packet of sequence number S6 istransmitted having, in its packet, the sequence number S4 andretransmission count 2 of the high priority packet (S4,2) as well as thesequence number S6 of this packet.

[0184] Since errors have occurred during transmission of the highpriority packets (S2,2) and (S4,2), these packets are not received atthe receiving end, and only the packet (S6) is received.

[0185] In this state, at the receiving end, it is known that themost-recently received high priority packet has the sequence number S1,and the error packet has the sequence number S4 and the retransmissioncount 2.

[0186] So, the receiving end sends a retransmission request for the highpriority packet (S4,2), together with the sequence number S1 of themost-recently received high priority packet as well as the sequencenumber S4 and retransmission count 2 of this packet.

[0187] Then, at the transmitting end, the sequence number S1 of themost-recently received; high priority packet is compared with thesequence number S4 of the error packet for which the retransmissionrequest has been made. In this case, since the sequence number S1 of themost-recently received high priority packet is smaller than the sequencenumber 54 of the error packet the transmitting end performs selectiveretransmission for those packets having sequence numbers which arelarger than the sequence number S1 and equal to or smaller than thesequence number S4.

[0188] That is, the high priority packet (S2,3) is transmitted, having,in its header, the sequence number S4 and retransmission count 2 of thehigh priority packet (S4,2) as well as the sequence number S2 andretransmission count 3 of this packet and, subsequently, the highpriority packet (S4,3) is transmitted, having, in its header, thesequence number S2 and retransmission count 3 of the high prioritypacket (S2,3) as well as the sequence number S4 and retransmission count3 of this packet.

[0189] As described above, according to the fourth embodiment, when thesequence number of the most-recently received high priority packet islarger than the sequence number of the error packet, the transmittingend retransmits only the error packet. Therefore, retransmission of theerror packet can be performed efficiently.

[0190] In this fourth embodiment, emphasis has been placed on the casewhere one data receiving apparatus is provided for one data transmissionapparatus. However, the selective retransmission process of this fourthembodiment can be applied to multicast having a plurality of datareceiving apparatuses for one data transmission apparatus. Hereinafter,a selective retransmission process applicable to multicast will bedescribed as a modification of the fourth embodiment.

[0191] [Modification of Embodiment 4]

[0192]FIG. 15 is a sequence diagram for explaining a data transmissionmethod according to a modification of the fourth embodiment,illustrating an example of selective retransmission in the case where aplurality of data receiving apparatuses are provided for one datatransmission apparatus.

[0193] Initially, as shown in FIG. 15, at a predetermined transmissiontiming, the high priority packet (S1,1) is transmitted, having, in itsheader, the sequence number and retransmission count of a previous highpriority packet as well as the sequence number S1 and retransmissioncount 1 of this packet. In this case, there are two receiving ends forthe transmitting end, i.e., the receiving end I and the receiving endII, and transmission of the high priority packet (S1,1) is errortransmission.

[0194] In this case, each receiving end sends a retransmission requestfor the high priority packet (S1,1), together with the sequence number(lastS) of the most-recently received high priority packet.

[0195] In response to the retransmission request from the receiving endI, the transmitting end retransmits the high priority packet (S1,2).However, after this retransmission, the transmitting end does notperform retransmission in response to the retransmission request fromthe receiving end II, because the high priority packet (S1,2) hasalready been retransmitted in response to the retransmission requestfrom the receiving end II.

[0196] As the result of the retransmission of the high priority packet(S1,2), the receiving end I receives the high priority packet (S1) whilethe receiving end II does not receive the high priority packet (S1).

[0197] In this case, the receiving end II outputs a retransmissionrequest for the high priority packet (S1,2). In response to thisrequest, the transmitting end increments the retransmission count andretransmits the high priority packet (S1,3).

[0198] In the fourth embodiment and the modification thereof, an upperlimit may be set for the retransmission count. Further, the upper limitof the retransmission count may be changed according to the priorityvalue of the packet.

[0199] [Embodiment 5]

[0200]FIGS. 16 and 17 are diagrams for explaining a data transmissionmethod according to a fifth embodiment of the present invention.

[0201] According to the data transmission method of this fifthembodiment, in the data transmission method of the first embodimentabsence of a sequence number is detected at the receiving end, and aretransmission request for a packet having the absent sequence number ismade by using this sequence number. At the transmitting end, when thepacket of the sequence number for which the retransmission request hasbeen output from the receiving end is stored in the retransmissionbuffer 17, retransmission of this packet is performed. At thetransmitting end, only high priority packets are stored in theretransmission buffer 17.

[0202] FIGS. 16(a) and 16(b) are block diagrams illustrating a datatransmission apparatus 105 and a data, receiving apparatus 205,respectively, in a data transmission system which performs real-timedata transmission by the data transmission method of this fifthembodiment.

[0203] The data transmission apparatus 105 is identical in structure tothe data transmission apparatus 101 of the first embodiment. The datareceiving apparatus 205 includes a receiving unit 21, an error packetdetection unit 22, a packet decoding unit 23, and a reception historymanagement unit 24, like the data receiving apparatus 201 of the firstembodiment. The receiving unit 21 receives packets transmitted from arelay server (data transmission apparatus at the transmitting end). Theerror packet detection unit 22 detects an error packet in which an errorhas occurred during transmission, in accordance with the output from thereceiving unit 21, and outputs a normal packet which has beentransmitted without a transmission error. The packet decoding unit 23receives the normal packet to decode coded data of the normal packet.The reception history management unit 24 manages the reception historyof packets.

[0204] The data receiving apparatus 205 of this fifth embodiment has aretransmission instruction output unit 26 b which outputs aretransmission request for a packet corresponding to the absent sequencenumber detected by the error packet detection unit 22, instead of theretransmission instruction output unit 26 of the data receivingapparatus 201 of the first embodiment.

[0205] Next, the function and effect will be described.

[0206]FIG. 17 is a sequence diagram for explaining packet selectiveretransmission control in the data transmission method of this fifthembodiment.

[0207] When a high priority packet (S1) of sequence number S1, which hasbeen output from the data transmission apparatus (transmitting end) 105;is not received by the data receiving apparatus (receiving end) 205 dueto a transmission error, in the data receiving apparatus 205; the errorpacket detection unit 22 detects that the sequence number S1 is absent,and a retransmission request for the packet of this sequence number S1is output to the transmitting end.

[0208] At the transmitting end, it is decided whether the packet of theretransmission request is stored in the retransmission buffer 17 or not.In this case, since the packet of the retransmission request is a highpriority packet, it is stored in the retransmission buffer 17.Therefore, the transmitting end performs retransmission of this packet.

[0209] Further, when a packet (S2) of sequence number S2, which has beenoutput from the data transmission apparatus (transmitting end) 105, isnot received by the data receiving apparatus (receiving end) 205 due toa transmission error, in the data receiving apparatus 205, the errorpacket detection unit 22, detects that the sequence number S2 is absent,and a retransmission request, for the packet of this sequence number S2is output to the transmitting end.

[0210] At the transmitting end, it is decided whether the packet of theretransmission request is stored in the retransmission buffer 17 or not.In this case, since the packet of the retransmission request is not ahigh priority packet, it is not stored in the retransmission buffer 17.Therefore, the transmitting end does not perform retransmission of thispacket.

[0211] As described above, according to the fifth embodiment of theinvention, the receiving end detects the absence of sequence number, andinstructs the transmitting end to retransmit the packet of the absentsequence number by using this sequence number. Then, the transmittingend retransmits the packet of the sequence number indicated by theinstruction from the receiving end when this packet is stored in theretransmission buffer. Therefore, the transmission quality in thewireless section in real-time transmission can be improved and,furthermore, the number of retransmission times can be reduced.

[0212] [Embodiment 6]

[0213] FIGS. 18-20 are diagrams for explaining a data transmissionmethod according to a sixth embodiment of the present inventions.

[0214] In the data transmission method of this sixth embodiment, datatransmission from the transmitting end to the receiving end iscontinuously performed in units of packets each having additionalinformation relating to its sequence number, priority and datareproduction time and, simultaneously, data in the packets received atthe receiving end are successively reproduced. At this time, only thepacket which can arrive at the receiving end within the time limit isretransmitted.

[0215]FIG. 18 is a block diagram illustrating a data transmissionapparatus 106 in a data transmission system which performs real-timedata transmission by the data transmission method of this sixthembodiment.

[0216] This data transmission apparatus 106 constitutes a relay server(transmitting end) which relays data transmitted between distributionserver and a terminal 9 (receiving end). The data transmission apparatus106 includes a reproduction time decision unit 39, in addition to theconstituents of the data transmission apparatus 101 of the firstembodiment. The reproduction time decision unit 39 decides a packetwhich cannot arrive at the receiving end within the reproduction time,amongst the packets to be transmitted. In the transmission unit 13 b,the packet decided in the reproduction time decision unit 39 is nottransmitted to the receiving end whether it is stored in theretransmission buffer 17 or not.

[0217] Other constituents of the data transmission apparatus 106 areidentical to those of the data transmission apparatus 101 of the firstembodiment.

[0218]FIG. 19, is a block diagram illustrating a data receivingapparatus 206 in the data transmission system which performs real-timedata transmission according to the data transmission method of the sixthembodiment.

[0219] The data receiving apparatus 206 includes a reproduction timedecision unit 43, instead of the packet priority decision unit 25 of thedata receiving apparatus 201 of the first embodiment. The reproductiontime decision unit 43 detects the reproduction time which is given tothe error packet detected by the error packet detection unit 22 and thearrival time of the error packet at the receiving end, decides thearrival time limit based on the reproduction time, and decides whetheror not the error packet has arrived at the receiving end before thearrival time limit. On the basis of the result of the decision, theretransmission instruction output unit 26 instructs the transmitting endto retransmit the error packet which has arrived at the receiving endbefore the arrival time limit, by using the sequence number of thepacket. The decision of the arrival time limit by the reproduction timedecision unit 43 is performed based on at least one of the allowablepacket delay time which is decided at the receiving end, and the packettransmission delay time between the transmitting end and the receivingend.

[0220] Other constituents of the data receiving apparatus 206 areidentical to those of the data receiving apparatus 201 of the firstembodiment.

[0221] As for the method of deciding the arrival time limit, it will bedescribed in detail as an eighth embodiment of the present invention.

[0222] Next, the function and effect will be described.

[0223]FIG. 20 is a sequence diagram for explaining packet retransmissioncontrol with time limit, in the data transmission method according tothis sixth embodiment.

[0224] In the data transmission apparatus (transmitting end) 106, eachpacket to be transmitted is given a reproduction time at the receivingend.

[0225] For example, when high priority packets (S1) and (S2) havingsequence numbers S1 and S2, which have been transmitted from the datatransmission apparatus (transmitting end) 106, are not normally receivedat the data receiving apparatus (receiving end) 206 due to atransmission error, in the data receiving apparatus 206, the errorpacket detection unit 22 decides that these high priority packets (S1)and (S2) are error packets. Further, the reproduction time decision unit43 detects the reproduction times (T1) and (T2) and the arrival times ofthese error packets, decides the arrival time limits (T1+α) and (T2+α)in accordance with the reproduction times, and decides whether or notthese error packets have arrived at the receiving end before the arrivaltime limits, respectively.

[0226] Since the high priority packet (S1) has arrived at the receivingend before the time limit, the transmitting end instructs thetransmitting end to retransmit this packet.

[0227] On the other hand, since the high priority packet (S2) has notarrived at the receiving end before the time limit, the receiving enddoes not instruct the transmitting end to retransmit this packet.

[0228] In the data transmission apparatus 106, when the data of thepacket having the sequence number indicated by the retransmissionrequest from the receiving end, is stored in the retransmission buffer,the data of the packet the transmission time of which does not pass thereproduction time is retransmitted to the receiving end. On the otherhand, as for the data of the packet the transmission time of which haspassed the reproduction time, this data is discarded without beingtransmitted, and the data in the retransmission buffer is discardedsuccessively from the packet which cannot arrive at the receiving endwithin the data reproduction time.

[0229] As described above, according to the sixth embodiment of thepresent invention, data transmission from the transmitting end to thereceiving end is continuously performed in units of packets each havingadditional information relating to its sequence number, priority, anddata reproduction time at the receiving end and, simultaneously, data ofthe packets received at the receiving end are successively reproduced.At this time, only the packets which have arrived at the receiving endwithin the time limit at the receiving end, are retransmitted to thetransmitting end. Therefore, the transmission quality of wirelesssections in real-time transmission is improved and, moreover, the numberof retransmission times can be reduced.

[0230] While in this sixth embodiment emphasis has been placed on themethod for recovering errors of data in packets there is a case whereadditional information added to the packet header (i.e., the sequencenumber, the reproduction time, etc.) has an error. There are variousmethods of recovering the additional information as well as, recoveringthe errors in data. Hereinafter, these methods will be described asmodifications of the sixth embodiment.

[0231] [Modification 1 of Embodiment 6]

[0232] In a first modification of the sixth embodiment, in addition tothe processes at the transmitting end and the receiving end in the datatransmission method of the, sixth embodiment, at the transmitting end,error correction codes for the sequence number and the reproduction timeare given to the packet to be transmitted. At the receiving end, errorcorrection for the sequence number and the reproduction time isperformed by utilizing the error correction codes and, thereafter, errorpacket retransmission control is performed on the basis of the decidedarrival limit time.

[0233] In the first modification of the sixth embodiment so constructed,even when the sequence number and the reproduction time of the errorpacket have errors, these additional information can be corrected.

[0234] [Modification 2 of Embodiment 6]

[0235] In a second modification of the sixth embodiment, in addition tothe processes at the transmitting end and the receiving end in the datatransmission method of the sixth embodiment, at the transmitting end,the sequence number and the reproduction time of a predetermined packetare embedded in a packet to be transmitted next. At the receiving end,the embedded information (i.e., the sequence number and the reproductiontime) of the previous packet (the predetermined packet) is extractedwhen the next packet is received. On the basis of this information, thearrival time limit of the predetermined packet is decided; andretransmission control is performed for the predetermined packet as anerror packet.

[0236]FIG. 21 is a sequence diagram for explaining packet dataretransmission control with time limit, in a data communication systemaccording to the second modification of the sixth embodiment.

[0237] At the transmitting end, a predetermined packet is given thesequence number and the reproduction time at the receiving end, and thesequence number and the reproduction time of this predetermined packetare also embedded in a next packet which is to be transmitted next tothe predetermined packet.

[0238] Thereafter, as shown in FIG. 21, packets (S1) and (S2) ofsequence numbers S1 and S2 are transmitted from the transmitting end,and the packet (S1) is not normally received at the receiving end due toa transmission error. Even in this case, as long as the packet (S2) isnormally received at the receiving end, the receiving end can detect thesequence number S1 and the reproduction time, (T1) of the packet (S1)previous to the packet (S2).

[0239] So, at the receiving end, the arrival time limit (T1+α) isdecided on the basis of the reproduction time (T1) of the error packet(S1), and it is decided whether or not the receiving end can receive theretransmitted packet within the arrival time limit if a retransmissionrequest is made at this point of time. In this case, there is apossibility that the packet (S1) will arrive at the receiving, endbefore the time limit if a retransmission request for the packet (S1) ismade when receiving the packet (S2) and, therefore, the receiving endsends a retransmission request for the packet (S1) to the transmittingend.

[0240] Thereafter, as shown in FIG. 21, packets (S3) and (S4) ofsequence numbers S3 and S4 are transmitted from the transmitting end,and the packet (S3) is not normally received at the receiving end due toa transmission error. Even in this case, as long as the packet (4) isnormally received at the receiving end, the receiving end can detect thesequence number S3 and the reproduction time (T3) of the packet (S3)previous to the packet (S4).

[0241] So, at the receiving end, the arrival time limit (T3+α) isdecided on the basis of the reproduction time (T3) of the error packet(S3), and it, is decided whether the packet (S3) has arrived at thereceiving end before the time limit or not. In this case, since thepacket (S3) has not arrived at the receiving end before the time limit,the receiving end does not instruct the transmitting end to retransmitthe packet (S3).

[0242] In the second modification of the sixth embodiment soconstructed, at the transmitting end, the sequence number and thereproduction time of a predetermined packet are also embedded in apacket to be transmitted next to the predetermined packet. Therefore,even when errors occur in not only the data of the packet but also thesequence number and the reproduction time, the receiving end can make aretransmission request for the error packet. Moreover, since thereceiving end does not make a retransmission request for the packetwhich cannot arrive at the receiving end within the reproduction time atthe receiving end, the number of retransmission times can be reduced.

[0243] As still another modification, the selective retransmissioncontrol according to any of the first to fifth embodiments and theirmodifications may be combined with the time-limit retransmission controlaccording to any of the sixth embodiment and its modifications.

[0244] For example, the second embodiment in which each packet is givenerror correction codes for its sequence number and priority informationmay be combined with the first modification of the sixth embodiment inwhich each packet is given error correction codes for its sequencenumber and reproduction time (first combination). According to thiscombination, each packet is given error correction codes for itssequence number, priority information, and reproduction time.

[0245] Further, the third embodiment in which the sequence number andthe priority information of a predetermined packet are embedded in apacket to be transmitted next to the predetermined packet, may becombined with the second modification of the sixth embodiment in whichthe sequence number and the reproduction time of a predetermined packetare embedded in a packet to be transmitted next to the predeterminedpacket (second combination). According to this combination, the sequencenumber, the priority information, and the reproduction time of thepredetermined packet are embedded in the packet to be transmitted nextto the predetermined packet.

[0246] Further, the modification of the third embodiment in which theprocess of embedding the sequence number and the priority information ofa high priority packet to be transmitted into subsequent packets iscontinued until a next high priority packet is transmitted, may becombined with the second modification of the sixth embodiment in whichthe sequence number and the reproduction time of a predetermined packetare embedded in a packet to be transmitted next to the predeterminedpacket (third combination). According to this combination, the processof embedding the sequence number, the priority information, and thereproduction time of a high priority packet into subsequent, packets iscontinued until a next high priority packet is transmitted.

[0247] Furthermore, according to the combination of the selectiveretransmission control and the retransmission control with time limit(second or third combination), the quantity of data to be embedded inthe packet increases. Therefore, there is proposed a method of embeddinga difference between the header information (sequence number, priorityinformation, reproduction time) of a predetermined packet and the headerinformation of a subsequent packet, in the subsequent packet.

[0248] Hereinafter, this method will be described as a third,modification of the sixth embodiment.

[0249] [Modification 3 of Embodiment 6]

[0250]FIG. 22 is a sequence diagram for explaining packet,retransmission control with time limit, in the data transmission methodaccording to a third modification of the sixth embodiment.

[0251] At the transmitting end, in a packet to be transmitted next to apredetermined packet, difference information relating to the sequencenumbers and thee reproduction time of the predetermined packet which haspreviously been transmitted is embedded together with the sequencenumber and the reproduction time of this packet. This differenceinformation is composed of a difference between the sequence number ofthe predetermined packet and the sequence number of the next packet(sequence difference) and a difference between the reproduction time ofthe predetermined packet and the reproduction time of the next packet(time difference).

[0252] For example, as shown in FIG. 22, packets (S1) and (S2) ofsequence numbers S1 and S2 are transmitted from the transmitting end,and the packet (S1) is not normally received at the receiving end due totransmission error. Even in this case, as long as the packet (S2) isnormally received at the receiving end, the receiving end can obtain thesequence number S1 and the reproduction time (T1) of the packet (S1)previous td the packet (S2).

[0253] That is, the sequence number S1 of the packet (S1) can beobtained by subtracting the sequence difference (S2−S1) from thesequence number S2 of the packet (S2). Further, the reproduction time(T1) of the packet (S1) can be obtained by subtracting the differencetime (T2−T1) from the reproduction time (T2) of the packet (S2).

[0254] Therefore, at the receiving end, the arrival time limit (T1+α) isdecided on; the basis of the reproduction time (T1) of the error packet(S1), and it is decided whether this packet has arrived at the receivingend before the arrival time limit or not. For example, when the packet(S1) has arrived at the receiving end before the arrival time limit, thereceiving end instructs the transmitting end to retransmit the packet(S1), by using the sequence number S1.

[0255] In the third modification of the sixth embodiment so constructed,since a difference between the header information (sequence numberpriority information, reproduction time) of a predetermined packet andthe header information of a subsequence packet is embedded in thesubsequence packet, the quantity of information to be embedded in thepacket is reduced.

[0256] While in the third modification of the sixth embodiment thesequence number and the reproduction time are described as informationto be embedded in the subsequent packet, information to be embedded isnot restricted thereto. For example, in addition to the sequence numberand the reproduction time, the retransmission count and the priority maybe embedded.

[0257] Hereinafter, a description will, be given of embodiments relatingto application sections of the retransmission control of the datatransmission methods according to the aforementioned embodiments.

[0258] [Embodiment 7]

[0259] In a data transmission method according to a seventh embodimentof the invention, data transmission between a distribution server and aterminal is per formed in packet units through a relay server and, atthe terminal end, data of received packets are successively reproduced.When a transmission error occurs between the relay server and theterminal, the relay server performs retransmission of the error packetin accordance with a retransmission request from the terminal. When atransmission error occurs between the distribution server and the relayserver, the distribution server performs retransmission of the errorpacket in accordance with a retransmission request which is transmittedfrom the terminal through the relay server.

[0260]FIG. 23 is a block diagram for explaining a data transmissionmethod according to this seventh embodiment, illustrating a datatransmission apparatus 107 in a system performing data transmissionaccording to the data transmission method.

[0261] This data transmission apparatus 107 constitutes a relay server(transmitting end) which relays data transmitted between thedistribution server and the terminal (receiving end), and it includes aretransmission instruction output unit 51, in addition to theconstituents of the data transmission apparatus 101 of the firstembodiment. The retransmission instruction output unit 51 instructs thedistribution server to retransmit an error packet for which aretransmission request has been output from the terminal, on the basisof the result of decision in the retransmission propriety decision unit16. Other constituents of the data transmission apparatus 107 areidentical to those of the data transmission apparatus 101 of the firstembodiment.

[0262] Next, the function and effect will be described.

[0263] In the seventh embodiment so constructed, when data transmissionbetween the distribution server and the terminal is performed in packetunits, the data transmission apparatus 107 relays data between thedistribution server and the terminal.

[0264] When a transmission error occurs between the relay server (datatransmission apparatus 107) and the terminal, the relay server performsretransmission of the error packet. In this case, a retransmissionrequest for the error packet from the terminal is not relayed to thedistribution server.

[0265] Further, when a transmission error occurs between thedistribution server and the relay server (data transmission apparatus107), a retransmission request for the error packet from the terminal istransmitted to the distribution server, and the error packet which isretransmitted from the distribution server is relayed by the datatransmission apparatus 107 to be transmitted to the terminal.

[0266] In the seventh embodiment so constructed, when a transmissionerror occurs between the relay server (the data transmission apparatus)and the terminal, a retransmission request for the error packet from theterminal is not relayed to the distribution server, and the relay serverperforms retransmission for the error packet. Therefore, the number ofretransmission times between the distribution server and the relayserver can be reduced.

[0267] [Modification of Embodiment 7]

[0268] A modification of the seventh embodiment is a data transmissionmethod in which data transmission between a distribution server and aterminal is performed in packet units through a relay server and, at theterminal end, data of received packets are successively reproduced. Whena transmission error occurs between the distribution server and therelay server, the error packet is not transmitted to the terminal, butthe relay server transmits a retransmission request to the distributionserver and the error packet is retransmitted from the distributionserver to the relay server.

[0269]FIG. 24 is a block diagram illustrating a data transmissionapparatus 107 a in a data communication system according to themodification of the seventh embodiment.

[0270] The data transmission apparatus 107 a constitutes a relay server(transmitting end) which relays data transmitted between a distributionserver and a terminal (receiving end), and it includes an error packetdecision unit 22, a reception history management unit, 52, and aretransmission instruction output unit 51 a, in addition to theconstituents of the data transmission apparatus 101 of the firstembodiment. The error packet decision unit 22 decides whether eachpacket received is an error packet or not on the basis of the outputfrom the receiving unit 11 which receives packets from the distributionserver, and outputs normally received packets. The reception historymanagement unit 52 manages the history of the normally received packets.The retransmission instruction output unit 51 a instructs thedistribution server to retransmit the error packet, according to theresult of the decision in the retransmission decision unit 16, theresult of the detection in the error packet detection unit 22, and thecontent s of the reception history in the reception history managementunit 52. Other constituents of the data transmission apparatus 107 a areidentical to those of the data transmission apparatus 101 of the firstembodiment.

[0271] Next, the function and effect will be described.

[0272] In the modification of the seventh embodiment so constructed,when data transmission between the distribution server and the terminalis performed in packet units, the data transmission apparatus 107 arelays the data between the distribution server and the terminal.

[0273] When a transmission error occurs between the relay server (datatransmission apparatus 107 a) and the terminal, the relay serverperforms retransmission of the error packet. In this case, aretransmission request for the error packet from the terminal is notrelayed to the distribution server.

[0274] Further, when a transmission error occurs between thedistribution server and the relay server (data transmission apparatus107 a) the error packet is not transmitted to the terminal, but aretransmission request from the relay server is transmitted to thedistribution server and the error packet is retransmitted from thedistribution server to the relay server.

[0275] Then, the relay server transmits the error packet retransmittedfrom the distribution server, to the terminal.

[0276] In the modification of the seventh embodiment, when atransmission error occurs between the distribution server and the relayserver, the error packet is not transmitted to the terminal, but therelay server outputs a retransmission request to the distribution serverand thereby the distribution server retransmits the error packet to therelay server. Therefore, wasteful transmission of the error packet fromthe relay server to the terminal is avoided.

[0277] [Embodiment 8]

[0278] FIGS. 25˜27 are diagrams for explaining a data transmissionmethod according to an eighth embodiment of the present invention.

[0279] In this data transmission method, data transmission between adistribution server and a terminal is performed in packet units and, atthe terminal end, data of received packets are successively reproduced.Further, information about a reproduction delay time which is allowablefor the data reproduction time at the terminal end, is transmitted, fromthe terminal to the distribution server. In the distribution server, thereproduction time at the terminal is estimated on the basis of thereproduction delay time and the transmission delay time which isrequired for data transmission between the distribution server and theterminal.

[0280]FIG. 25 is a block diagram illustrating a data transmissionapparatus 108 in a data communication system according, to this eighthembodiment of the invention.

[0281] This data transmission apparatus 108 constitutes a relay server(transmitting end) which relays data transmission between a distributionserver and a terminal (receiving end), and it includes a receiving unit11, a transmission queue management unit 12, and a transmission unit 13.The receiving unit 11 receives packets transmitted from the distributionserver. The transmission queue management unit 12 sets the transmissionorder of the received packets, in accordance with additionalinformation, such as a sequence number, which is given to each packet.The transmission unit 13 transmits the packets in the transmission orderwhich is set by the unit 12.

[0282] The data transmission apparatus 108 further includes a time stampextraction unit 75 and an allowable reproduction delay informationreceiving unit 72. The time stamp extraction unit 75 extracts a timestamp which is given to each packet as time information, through thetransmission unit 13. The allowable reproduction delay informationreceiving unit 72 receives information relating to the allowablereproduction delay time (arrival time limit) from the receiving end(terminal).

[0283] Further, the data transmission apparatus 108 includes atransmission delay measurement packet transmitting and receiving unit71, and a transmission delay measurement unit 73. The transmission delaymeasurement packet transmitting and receiving unit 71 performstransmission and reception of a packet used for measuring a transmissiondelay (transmission delay measurement packet). The transmission delaymeasurement unit 73 measures a transmission delay in accordance with thetime required for forward and backward transmission of the transmissiondelay measurement packet between the transmitting end and the receivingend.

[0284] Further, the data transmission apparatus 108 includes areproduction time calculation unit 74 which estimates the datareproduction time at the receiving end, in accordance with thetransmission delay, the time stamp, and the allowable reproduction delaytime (arrival time limit), and outputs the estimated reproduction time.

[0285] Furthermore, like the data transmission apparatus according toembodiment 1 or 6, the data transmission apparatus 108 has the functionof storing a packet the priority of which is equal to or higher than apredetermined value in a retransmission buffer and discarding a packetwhich cannot be in the time for retransmissions and the function ofretransmitting a packet for which a retransmission request is outputfrom the receiving end, although these functions are not shown in thefigure.

[0286] To be specific, the data transmission apparatus 108 includes theconstituents corresponding to the retransmission instruction receivingunit 14, the packet priority decision unit 15, the retransmissiondecision unit 16, the retransmission buffer 17, and the retransmissionbuffer management unit 18 which are included in the data transmissionapparatus 101 of the first embodiment. In the transmission queuemanagement unit 12, setting of the packet transmission order isperformed on all the packets to be transmitted, including not only thereceived packets but also the packets to be transmitted.

[0287]FIG. 26 is a block diagram illustrating a data receiving apparatus208 in the data transmission system which performs real-time datatransmission by the data transmission method according to this eighthembodiment.

[0288] The data receiving apparatus 208 includes a receiving unit 21which receives packets transmitted from the relay server (datatransmission apparatus at the transmitting end), and a packet decodingunit 23 which decodes the received packets.

[0289] The data receiving apparatus 208 further includes a transmissiondelay measurement packet transmitting and receiving unit 62, anallowable reproduction delay decision unit 63, and an allowablereproduction delay information transmitting unit 61. The transmissiondelay measurement packet transmitting and receiving unit 62 receives thetransmission delay measurement packet which has been transmitted fromthe transmission delay measurement packet transmitting and receivingunit 71 at the transmitting end, and returns it to the transmitting end.The allowable reproduction delay decision unit 63 decides an allowablereproduction delay time, and outputs information relating to this. Theallowable reproduction delay information transmitting unit 61 transmitsthe information relating to the allowable reproduction delay time, tothe transmitting end.

[0290] Furthermore, like the data receiving apparatuses according toembodiments 1 and 6, the data receiving apparatus 208 has the functionof detecting error packets and outputting a retransmission request foran error packet which can be in the time for retransmission, althoughthis is not shown in the figure.

[0291] To be specific, the data receiving apparatus 208 includes theconstituents corresponding to the error packet detection unit 22, thereception history management unit 24, the packet priority decision unit25, and the retransmission instruction output unit 26 which are includedin the data receiving apparatus 201 of the first embodiment.

[0292] Next, the function and effect will be described.

[0293] FIGS. 27(a) and 27(b) are diagrams for explaining a method forestimating the data reproduction time at the terminal, in the serveraccording to this eighth embodiment. More specifically,

[0294]FIG. 27(a) shows the relationship between the packet time stampand the packet output time (reproduction time) or the like, and

[0295]FIG. 27(b) shows a method for mapping the time stamp to thestandard time.

[0296] In the data transmission apparatus (transmitting end) 108, whenthe transmission unit 13 performs packet transmission in accordance withthe transmission order which is set by the transmission queue managementunit 12, the time stamp t_(p) included in each packet is extracted bythe time stamp extraction unit 75, and output to the reproduction timecalculation unit 74. Further, the allowable reproduction delay timed_(p) which is decided by the decision unit 63 of the data receivingapparatus (receiving end) 208 and transmitted through the transmissionunit 61, is received by the allowable reproduction delay informationreceiving unit 72 and output to the reproduction time calculation unit74. Further, the transmission delay measurement packet is transmittedfrom the, transmission delay measurement packet transmitting andreceiving unit 71 at the transmitting end to the transmission delaymeasurement packet transmitting and receiving unit 62 at the receivingend, sand the transmission delay measurement packet is returned from thetransmitting and receiving unit 62 at the receiving end to thetransmitting and receiving unit 72 at the transmitting end, whereby theserver-to-terminal transmission delay d_(s) is obtained by thetransmission delay measurement unit 73 and output to the reproductiontime calculation unit 74. The time when each packet is output from theserver is measured at the transmitting end.

[0297] Then, the reproduction time calculation unit 74 estimates thereproduction time (packet output time) t_(o) of each packet at thereceiving end.

[0298] To be specific, as shown in FIG. 27(a), the packet output timet_(o) is obtained by adding the allowable reproduction delay time d_(p)to the time stamp t_(p), and the terminal reception time t_(r) isobtained by adding the server-to-terminal transmission delay d_(s) tothe server output time t_(s). Accordingly, the reproduction timecalculation unit 74 obtains the packet output time t_(o) by(t_(p)+d_(p)) and the terminal reception time t_(r) by (t_(s)+d_(s)).

[0299] Thereafter, in the data transmission apparatus 108, on the basisof comparison between (t_(s)+d_(s)) and (t_(p)+d_(p)) it is decidedwhether the transmission packet can arrive at the receiving end beforethe reproduction time or not, i.e., whether the relationship, terminalreception time t_(r)≦packet output time t_(o), is satisfied or not.Based on the result of this decision, retransmission of the error packetrequested, and discard of the packet in the retransmission buffer areperformed.

[0300] While in this eighth embodiment the reproduction delay d_(p) istransmitted from the receiving terminal to the server, this may be afixed value. Further, temporal synchronization between the server andthe terminal is made by, for example NTP (network time protocol) ofInternet standard.

[0301] Further, the time stamp t_(p) of each packet is obtained from thetime stamp of the RTP header, this time stamp value must be mapped ontothe same, time axis as the server output time or the like.

[0302] Hereinafter, the RTP time stamp mapping method in the relayserver will be described briefly.

[0303] Since the RTP time stamp is not expressed directly by thestandard time, it is mapped to time information based on the standardtime, by using information included in other standard protocols RTCP.(Real-Time Control Protocol) and RTSP (Real-Time Stream Protocol). Therelay server (data transmission apparatus) 108 must know this mappinginformation and, therefore, the relay, server 108 obtains this mappinginformation when it relays the mapping information.

[0304] For example, as shown in FIG. 27(b), when the mapping informationfor the time stamps included in the Internet standard protocols RTCP andRTSP, which is output from the server S, is relayed by the relay serverIS to the terminal T, the mapping information is analyzed by the relayserver IS. Further, the mapping information for the time stamps at theterminal is transmitted from the terminal to the server.

[0305] As described above, according to the eighth embodiment, since theserver (data transmission apparatus) estimates the actual output time(reproduction time) of each packet at the terminal, a packet whichcannot be in time for reproduction can be eliminated from theretransmission buffer.

[0306] In this eighth embodiment, the method for deciding thetransmission delay time and the allowable reproduction delay time is notrestricted to the above-mentioned method. For example, during datareproduction at the receiving end, the transmission delay between theserver and the terminal may be dynamically updated according to theinformation from the receiving end. Alternatively, during datareproduction at the receiving end, the allowable reproduction delay maybe measured and changed dynamically.

[0307] Furthermore, while in this eighth embodiment the actual outputtime (reproduction time) of each packet at the terminal is estimated inthe relay server (data transmission apparatus), it may be estimated inthe distribution server in accordance with the allowable reproductiondelay time from the terminal or the transmission delay time required fordata transmission between the distribution server and the terminal.

[0308] [Embodiment 9]

[0309] FIGS. 29˜31 are diagrams for explaining a data transmissionmethod according to a ninth embodiment of the present invention. In thedata transmission method of this ninth embodiment, data transmissionfrom the transmitting end to the receiving end is continuously performedin units of packets each having additional information relating to itssequence number, priority, and data reproduction time at the receivingend, which are required to realize real-time transmission in packetunits, while successively reproducing data of the packets received atthe receiving end. At this time, only error packets the priorities ofwhich are equal to or higher than, a predetermined value areretransmitted.

[0310]FIG. 29(a) is a block diagram illustrating a data transmissionapparatus 109 in a data transmission system which performs real-timedata transmission according to the data transmission method of thisninth embodiment.

[0311] The data transmission apparatus 109 constitutes a relay server(transmitting end) which relays data transmitted between a distributionserver and a terminal (receiving end). The data transmission apparatus109 includes a receiving unit 11, a transmission queue management unit12, and a transmission unit 13. The receiving unit 11 receives packetstransmitted from the distribution server. The transmission queuemanagement unit 12 sets the transmission order of the received packetsand the packets to be retransmitted (retransmission packets) inaccordance with the above-described additional information. Thetransmission unit 13 transmits the packet data in the transmission orderwhich has been set by the transmission queue management unit 12.

[0312] The data transmission apparatus 109 further includes a highpriority sequence number management unit 81, a sequence numbercorrespondence management unit 82, and a high priority sequence numberinsertion unit 83. When the priority of a packet transmitted by thetransmission unit 13 is equal to or higher than a predetermined value,the high priority sequence number management unit 81 increments thevalue of the sequence number which corresponds to only the high prioritypacket (high priority sequence number), and stores the incrementedvalue. The sequence number correspondence management unit 82 stores thecorrespondence between the value of the sequence number of thetransmitted high priority packet and the value of the incremented highpriority sequence number of this high priority packet. The highpriority, sequence insertion unit 83 outputs the value of the highpriority sequence number of each high priority packet, which is storedin the management unit 81, so that it is inserted in the packet to betransmitted.

[0313] The high priority sequence numbers managed by the high prioritysequence number management unit 81 correspond to the number of highpriority packets transmitted from the transmitting end.

[0314] Further, the data transmission apparatus 109 includes aretransmission buffer 17, a packet priority decision unit 15, and aretransmission buffer management unit 18. The retransmission buffer 17stores predetermined packets amongst the received packets, asretransmission packets. The packet priority decision unit 15 decides thepriorities of the received packets. The retransmission buffer managementunit 18 controls the retransmission buffer 17 such that data of packetsthe priorities of which are equal to or higher than a predeterminedvalue are stored in the buffer 17, in accordance with the decidedpriorities of the packets.

[0315] Further, the data transmission apparatus, 109 includes aretransmission instruction receiving unit 14 and a retransmissiondecision unit 16 c. The retransmission instruction receiving unit 14receives a retransmission request indicating a high priority sequencenumber, from the terminal at the receiving end. The retransmissiondecision unit 16 c decides whether retransmission of a packet for whichthe retransmission request has been made is performed or not. Theretransmission decision unit 16 retrieves the management information inthe sequence number correspondence management unit 82, in accordancewith the high priority sequence number indicated by the retransmissionrequest, to obtain the sequence number corresponding to the highpriority sequence number used for the retransmission request, anddecides that the requested packet is to be retransmitted, only when thepacket of the sequence number is stored in the retransmission buffer 17.

[0316] In FIG. 29(a), real-time data transmission is performed in packetunits between the distribution server and the terminal through the relayserver or the like, and the data transmission apparatus 109 constitutesthe relay server. However, the relay server may serve as thedistribution server. To be specific, when the data transmissionapparatus serves as the distribution server, it is constructed as shownin FIG. 29(b). In FIG. 29(b), the receiving unit 11 of the datatransmission apparatus 109 is replaced with a coded packet generationunit 10 a which encodes the data and outputs the coded data in packetunits, and a priority allocation unit 10 b which allocates additionalinformation, such as a priority, to each packet output from the codedpacket generation unit 10 a.

[0317]FIG. 30 is a block diagram illustrating a data receiving apparatus209 in the data transmission system which performs real-time datatransmission according to the data transmission method of the ninthembodiment.

[0318] The data receiving apparatus 209 includes a receiving unit 21, anerror packet detection unit 22 a, and a packet decoding unit 23. Thereceiving unit 21 receives the packets transmitted from the datatransmission apparatus at the transmitting end. The error packetdetection unit 22 a detects error packets in which errors have occurredduring transmission and outputs normal packets which have beentransmitted without transmission errors. The packet decoding unit 23receives the normal packets and decodes the coded data of the normalpackets.

[0319] When the high priority sequence number inserted in the packetfrom the data transmission apparatus (transmitting end high prioritysequence number) is correctly extracted, the error packet detection unit22 a outputs both of the value of the transmitting end high prioritysequence number and the value of the receiving end high prioritysequence number at this point of time. The value of the receiving endhigh priority number corresponds to the number of the high prioritypackets received at the receiving end, and this value is incrementedevery time a high priority packet is received at the receiving end.

[0320] Further, the data receiving apparatus 209 includes a highpriority sequence number management unit 91 and are transmissionsequence number decision unit 92. When the error packet detection unit122 a outputs a normal packet, the high priority sequence numbermanagement unit 91 increments the value of the receiving end highpriority sequence number and stores it. The retransmission sequencenumber decision unit 92 compares the value of the transmitting end highpriority sequence number output from the error packet detection unit 22a with the value of the receiving end high priority sequence number.When these values are not equal, the decision unit 92 outputs the valuesranging from the value obtained by adding 1 to the value of thereceiving end high priority sequence number to the value of thetransmitting end high priority sequence number, as the values ofretransmission sequence numbers (transmitting end high-priority sequencenumbers).

[0321] The high priority sequence number management unit 91 incrementsthe value of the stored receiving end high priority sequence numberevery time the retransmission sequence number decision unit 92 outputs ahigh priority sequence number.

[0322] Further, the data receiving unit 209 includes a retransmissioninstruction output unit 26 c which outputs a retransmission request foran error packet to the transmitting end, on the basis of thetransmitting end high priority sequence number which is output as aretransmission sequence number from the retransmission sequence numberdecision unit 92.

[0323] Next, the function and effect will be described.

[0324]FIG. 31 is a sequence diagram for explaining the selective packetretransmission control in the data transmission method of this ninthembodiment.

[0325] In the description with respect to FIG. 31, a sequence number[S+n] indicates a sequence number having a value “S+n”, a sequencenumber [H+n], indicates a high priority sequence number having a value“H+n”, and a packet (S+n) indicates a packet having a sequence numberthe value of which is “S+n”. Further, n is any of 0, l, 2, 3, 4, and 5.

[0326] For example, assuming that the priorities equal to or higher thanthe predetermined value are high priorities while the priorities lowerthan the predetermined value are low priorities, as shown in FIG. 31,when an error has occurred during transmission of high priority packets(S+1) and (S+2) of sequence numbers [S+1] and [S+2], retransmissionrequests for these high priority packets are made at the receiving end.However, when an error has occurred during transmission of a lowpriority packet (S+3) of sequence number [S+3], no retransmissionrequest is made for this low priority packet (S+3).

[0327] To be specific, each packet transmitted from the distributionserver is given additional information relating to its sequence numberand priority. In the data transmission apparatus 109 as a relay server,the transmission order of the received packets is set by thetransmission queue management unit 12, and then the packets are suppliedto the transmission unit 13. On the other hand, the priorities of thereceived packets are decided by the packet priority decision unit 15.Then, in the transmission unit 13, transmission of these packets isperformed according to the transmission order which has been set.Further, those packets the priorities of which are decided as beingequal to or higher than the predetermined value are stored in theretransmission buffer 17 under control of the retransmission buffermanagement unit 17. Further, in the retransmission buffer 17, data aresuccessively released (discarded) from the packets which cannot be intime for reproduction, under control of the management unit 18.

[0328] Next, a description will be given of management of the sequencenumbers at the time of packet transmission.

[0329] When transmitting a high priority packet, the high prioritysequence number is incremented.

[0330] To be specific, when a high priority packet (S+0) of sequencenumber [S+0] is transmitted by the transmission unit 13, the value ofthe transmitting end high priority sequence number [H+0] which is storedin the high priority sequence number management unit 81 is incrementedto “H+1”. At this time, the value of the sequence number [S+0] of thehigh priority packet (S+0) and the incremented value of the transmittingend high priority sequence number [H+1] are entered, by one-to-onecorrespondence, in the sequence number correspondence management unit82.

[0331] Likewise, when a high priority packet (S+1) of sequence number[S+1] is transmitted by the transmission unit 13, the value of thetransmitting end high priority sequence number [H+1] which is stored inthe high priority sequence number management unit 81 is incremented to“H+2”. At this time, the value of the sequence number [S+1] of the highpriority packet (S+1) and the incremented value of the transmitting endhigh priority sequence number [H+2] are entered, by one-to-onecorrespondence, in the sequence number correspondence management unit82.

[0332] Further, also when a high priority packet (S+2) is transmitted,like the high priority packets (S+0) and (S+1), the transmitting endhigh priority sequence number [H+2] in the high priority sequence numbermanagement unit 81 is incremented, and the sequence number [S+2] of thehigh priority packet (S+2) and the incremented transmitting end highpriority sequence number [H+3] are entered, by one-to-onecorrespondence, in the sequence number correspondence management unit82.

[0333] On the other hand, when transmitting a low priority packet, thecorresponding low, priority sequence number is not incremented

[0334] To be specific, “when a low priority packet (S+3) of sequencenumber [S+3] is transmitted by the transmission unit 13, the value ofthe transmitting end high priority sequence number [H+3] stored in thehigh priority sequence number management unit 81 is not updated butmaintained as it is. At this time, the process of entering the sequencenumber of the transmitted packet and the transmitting end high prioritysequence number [H+3] which is stored in the high priority sequencenumber management unit 81, in the sequence number correspondencemanagement unit 82, is not performed.

[0335] Next, a description will be given of a sequence number embeddingprocess at the time of packet transmission.

[0336] When the high priority packet (S+1) is transmitted, the value ofthe transmitting end high priority sequence number [H+] which is storedin the high priority sequence number management unit 81 at this point oftime, is embedded in the header of the transmission packet (S+1) by thehigh priority sequence number insertion unit 83. Likewise, when the lowpriority packet (S+3) is transmitted, the value of the transmitting endhigh priority sequence number [H+3] which is stored in the high prioritysequence number management unit 81 at this point of time, is embedded inthe header of the transmission packet (S+3) by the high prioritysequence number insertion unit 83. Thereafter, the transmission packethaving the transmitting end high priority sequence number so embedded inits header, is transmitted to the receiving end by the transmission unit13.

[0337] Those packets output from the distribution server aresuccessively transmitted to the terminal (data receiving apparatus) 209through the relay server.

[0338] In the data receiving apparatus 209, the packets from the relayserver (data transmission apparatus) 109 are received by the receivingunit 21, and the received packets are supplied to the error packetdetection unit 22 a. The normally received high priority packet (S+0) isoutput from the error packet detection unit 22 a to the packet decodingunit 23, and the value of its receiving end high priority sequencenumber (i.e., the value of the high priority sequence number [H+0]stored in the high priority sequence number management unit 91) isincremented to “H+1”.

[0339] It is assumed that a transmission error has occurred duringtransmission of the high priority packets (S+1) and (S+2) and,thereafter, the low priority packet (S+3) subsequent to these packetshas been transmitted without a transmission error.

[0340] In this case, the normally transmitted low priority packet (S+3)is output from the error packet detection unit 22 a to the packetdecoding unit 23, but the value of the receiving end high prioritysequence number [H+1] which is stored in the high priority sequencenumber management unit 91 is not incremented.

[0341] Further, in the error packet detection unit 22 a, when thetransmitting end high priority sequence numbers [H+0] and [H+3] whichare inserted in the high priority packet (S+0) and the low prioritypacket (S+3), respectively, are correctly extracted, these transmittingend high priority sequence, numbers [H+0] and [H+3] are output to theretransmission sequence number decision unit 92. Further, the receivingend high priority sequence numbers [H+0] and [H+1] which are stored inthe high priority sequence” number management unit 91 at the time whenthe transmitting end high priority sequence numbers [H+0] and [H+3] areextracted by the error packet detection unit 22 a, are output to theretransmission sequence number decision unit 92.

[0342] For example, at the time when the transmitting end high prioritysequence number [H+0] is extracted, the value [H+0] of the receiving endhigh priority sequence number stored in the high priority sequencenumber management unit 91 as well as the transmitting end high prioritysequence number [H+0] are output to the retransmission sequence numberdecision unit 92. At the time when the transmitting end high prioritysequence number [H+3] is extracted, the value [H+1] of the receiving endhigh priority sequence number stored in the high priority sequencenumber management unit 91 as well as the transmitting end high prioritysequence number [H+3] are output to the retransmission sequence numberdecision unit 92.

[0343] In the retransmission sequence number decision unit 92, thetransmitting end high priority sequence number and the receiving endhigh priority sequence number, which have been supplied at the sametime, are compared, to decide whether retransmission is to be requestedto the transmitting end.

[0344] For example, as the result of the comparison between thetransmitting end high priority sequence number [H+0] and the receivingend high priority sequence number [H+0], since the values of these highpriority sequence numbers are equal, no transmission instruction isperformed. On the other hand, as the result of the comparison betweenthe transmitting end high priority sequence number [H+3] and thereceiving end high priority sequence number [H+1], since the values ofthese high priority sequence numbers are not equal, a retransmissioninstruction is performed. In this case, the values ranging from thevalue obtained by adding 1 to the value of the receiving end highpriority sequence number [H+1] to the value of the transmitting end highpriority sequence number [H+3], i.e., “H+1” and “H+3”, are output to theretransmission instruction output unit 26 as the values of the highpriority sequence numbers user for the retransmission instruction. Atthis time, in the high priority sequence, number management unit 91, thevalue of the stored receiving end high priority sequence number isincremented twice to be “H+3”.

[0345] On receipt of “H+2” and “H+3” as the values of the high prioritysequence numbers, the retransmission instruction output unit 26 outputsa retransmission request with the high priority sequence number [H+2]and a retransmission request with the high priority sequence number[H+3], to the transmitting end.

[0346] Then, in the data transmission apparatus 109 at the transmittingend, the retransmission requests are received by the retransmissioninstruction receiving unit 14, and the management information in thesequence number correspondence management unit 82 is retrieved on thebasis of the requested high priority sequence numbers [H+2] and [H+3],thereby obtaining the sequence number [S+1] corresponding to the highpriority sequence number [H+2] and the sequence number [S+2]corresponding to the high priority sequence number [H+3].

[0347] Further, in the retransmission decision unit 16 c, it is decidedwhether the data of the packets corresponding to the sequence numbers[S+1] and [S+2] are stored in the retransmission buffer 17 or not. Basedon the result of this decision, only the packets the data of which arestored in the retransmission buffer 17 are output as retransmissionpackets from the retransmission buffer 17 to the transmission queuemanagement unit 12. Here, the high priority packets (S+1) and (S+2) areoutput as retransmission packets.

[0348] In the retransmission queue management unit 12, the transmissionorder is set for these retransmission packets, and these packets areretransmitted to the receiving end through the transmission unit 13.Since the retransmission packets (S+1) and (S+2) are high prioritypackets, when transmitting these packets the values of theirtransmitting end high priority sequence numbers stored in the highpriority sequence number management unit 81 are incremented.

[0349] To be specific, when transmitting the retransmission packet(S+1), the value of the transmitting end high priority sequence number[H+3] stored in the high sequence number management unit 81 isincremented to “H+4”, and the sequence number [S+1] of theretransmission packet (S+1) and the transmitting end high prioritysequence number [H+4] are entered by one-to-one correspondence, in thesequence number correspondence management unit 82.

[0350] Further, when transmitting the retransmission packet (S+2) thevalue of the transmitting end high priority sequence number [H+4] storedin the high priority sequence number management unit S1 is incrementedto “H+5”, and the sequence number [S+2] of the retransmission packet(S+2) and the transmitting end high priority sequence number [H+5] areentered, by one-to-one correspondence, in the sequence numbercorrespondence management unit 82.

[0351] As described above, according to the ninth embodiment of theinvention, data transmission from the transmitting end to the receivingend is continuously performed in units of packets, each packet havingadditional information relating to its sequence number, priority, anddata reproduction time, and information relating to the high prioritysequence number managed at the transmitting end and, simultaneously,data of received packets are successively reproduced at the receivingend. The value of the transmitting end high priority sequence numberpossessed by the received packet (number of transmitted high prioritypackets is compared with the value of the receiving end high prioritysequence number, managed at the receiving end (number of received highpriority packets), and a retransmission request is made by indicating atransmitting end high priority sequence number which is absent.Therefore, the transmission quality of the ratio section in real-timetransmission can be improved by retransmission of error packets thepriorities of which are equal to or higher than a predetermined valueand, moreover, the retransmission of error packets can be realized bysimpler procedures.

[0352] In this ninth embodiment, when the high priority sequence numberscorresponding to plural high priority packets transmitter arecontinuously absent, the receiving end sends a retransmission requestfor each high priority packet having the absent high priority sequencenumber, to the transmitting end. However, retransmission requests forplural high priority packets may be sent collectively to thetransmitting end, by listing the values of the plural high prioritysequence numbers or indicating the range of these values.

[0353] In this case, at the transmitting end; based on the plural highpriority sequence numbers requested from the receiving end, the sequencenumbers corresponding to the respective transmitting end high prioritypackets are obtained by retrieval, and the high priority packets havingthe sequence numbers so obtained are retransmitted to the receiving end.

[0354] [Embodiment 10]

[0355] In a data transmission method according to a tenth embodiment ofthe present invention, the number of times of retransmission requests tothe transmitting end and the interval of the retransmission requests arechanged according to the transmission status of the radio section,whereby the probability of normal transmission of the retransmissionrequests to the transmitting end is increased to improve thetransmission quality in the radio section.

[0356]FIG. 32 is a block diagram illustrating a data transmissionapparatus 110 in a data transmission system performing real-time datatransmission according to the data transmission method of this tenthembodiment.

[0357] The data transmission apparatus 110 includes a retransmissiondecision unit 16 d, instead of the retransmission decision unit 16 c ofthe data transmission apparatus 109 of the ninth embodiment. Theretransmission decision unit 16 d performed the same process as that ofthe decision unit 16 c and, further, outputs the sequence number of thepacket which is decided to be transmitted. Further, the datatransmission apparatus 110 includes a sequence number correspondencemanagement unit 82 a, instead of the sequence number correspondencemanagement unit 82 of the data transmission apparatus 109. The sequencenumber correspondence management unit 82 a performs the same process asthat of the unit 82 and, further, deletes the value of the transmittingend high priority sequence number corresponding to the value of thesequence number supplied from the retransmission decision unit 16 d.Other constitutes of the data transmission apparatus 110 of this tenthembodiment are identical to those of the data transmission apparatus 109of the ninth embodiment.

[0358]FIG. 33 is a block diagram illustrating a data receiving apparatus210 in the data transmission system performing real-time datatransmission according to the data transmission method of this tenthembodiment.

[0359] The data receiving apparatus 210 includes an error packetdetection unit 22 b, instead of the error packet detection unit 22 a ofthe data receiving apparatus 209 of the ninth embodiment The errorpacket detection unit 22 b performs the same process a that of the unit22 a and, further, decides the transmission status of the radio section,from the number of the detected error packets.

[0360] Further, the data receiving apparatus 210 includes aretransmission instruction output unit 26 d, instead of theretransmission instruction output unit 26 c of the data receivingapparatus 209. The retransmission instruction output unit 26 d performsthe same process as that of the unit 26 c and, further, outputs thetransmitted retransmission request as a control signal.

[0361] Further, the data receiving apparatus 210 includes aretransmission instruction consecutive output unit 93 which receives thecontrol signal (retransmission request) output from the retransmissioninstruction output unit 26 d, and consecutively outputs theretransmission request by a predetermined number of times atpredetermined intervals. Further, the unit 93 changes the number ofoutput times of retransmission request and the output interval,according to information indicating the transmission status of the radiosection, which is output from the error packet detection unit 22 b.

[0362] Other constituents of the data receiving apparatus 210 of thistenth embodiment are identical to those of the data receiving apparatus209 of the ninth embodiment.

[0363] Next, the function and effect will be described.

[0364] Since the fundamental data transmission process according thedata transmission method of this tenth embodiment is identical to thatof the ninth embodiment, only a distinctive process of this tenthembodiment will be described hereinafter.

[0365] In this tenth embodiment, the packet from the transmitting end isreceived by the receiving unit 21 and output to the error packetdetection unit 22 b. In the error packet detection unit 22 b, thetransmission status of the radio section is detected according to theoutput of the receiving unit 21, and information indicating thetransmission status of the radio section is supplied to theretransmission instruction consecutive output unit 93.

[0366] On the other hand, when the high priority sequence number outputfrom the retransmission sequence output unit 92 is input to theretransmission instruction output unit 26 b, a retransmission requestindicating the high priority sequence number is output from theretransmission instruction output unit 26 b to the transmitting end and,simultaneously, this retransmission request is output as a controlsignal to the retransmission instruction consecutive output unit 93.

[0367] Then, the retransmission instruction consecutive output unit 93performs a consecutive retransmission process for consecutivelytransmitting the retransmission request by several times. In thisconsecutive retransmission process, the number transmission times of theretransmission request and the transmission interval are adjusted on thebasis of a predetermined value, according to the transmission status ofthe radio section which is obtained from the output information of theerror packet detection unit 22 b.

[0368] For example, when many transmission errors occur in the radiosection, the number of request transmission times is increased and theoutput interval is increased. Thereby, the probability of normaltransmission of the retransmission request to the transmitting endincreases. On the other hand, when not many transmission errors occur inthe radio section, the number of request transmission times isdecreased, and the output interval is narrowed. Thereby the timerequired for retransmission is reduced.

[0369] Further, at the transmitting end, packet retransmission iscarried out according to the retransmission request, and the sequencenumber correspondence management unit 82 a deletes the value of thetransmitting end high priority sequence number corresponding to thesequence number supplied from the retransmission decision unit 16 d.

[0370] Therefore, with respect to the same retransmission request whichis received again, retrieval for the sequence number corresponding tothis retransmission request by the retransmission decision unit 16 dends in failure because the correspondence between the transmitting endhigh priority sequence number indicated by this retransmission requestand the sequence number is deleted from the sequence numbercorrespondence management unit 82 a.

[0371] As the result, in the retransmission decision unit 16 d, it isdecided that no retransmission is performed for the high priority packetfor which the retransmission request has been made by indicating thevalue of the transmitting end high priority sequence number. Therefore,at the transmitting end, is avoided that the same packet is repeatedlyretransmitted where the same retransmission request is output severaltimes from the receiving end.

[0372] As described above, according to the tenth embodiment of thepresent invention, a retransmission request indicating the high prioritysequence number of a desired packet is consecutively transmitted severaltimes, from the receiving end to the transmitting end, againsttransmission errors. Therefore, when at least one of the severaltransmission requests from the receiving end is normally received at thetransmitting end, the error packet the priority of which is equal to orhigher than a predetermined value can be retransmitted, whereby thetransmission quality in the radio section in real-time transmission canbe effectively improved.

[0373] Hereinafter, a description will be given of the data structure ofa packet Pa for transmitting data by a data transmitting methodaccording to any of the aforementioned embodiments.

[0374] FIGS. 34(a)˜34(c) are diagrams illustrating the data structure ofthe packet Pa.

[0375] This packet Pa is composed of a header section Ph which containsrelevant information indicating the attribute of the packet, and a datasection Pd which stores data to be transmitted (FIG. 34(a)).

[0376] The header section Ph includes header information Ia indicatingthe sequence number corresponding to each packet, header information Ibindicating the reproduction time at the receiving end, of the data to betransmitted (time stamp) Ib, header information indicating the priorityof each packet, extension header information Id, and other headerinformation I to I10 (refer to FIG. 34(b)).

[0377] The specific convention of each header information is describedin RFC1889 as shown in FIG. 34(c). For example, the header informationI3 indicates that the extension header information Id is added to theheader section Ph when its value is 1. The header information I5indicates that the data stored in the data section is coded data by theMPEG1 method when its value PT is 32, and indicates that the data storedin the data section is coded data by the MPEG2 method when PT is 33.Further, each of the header information I9, Ic, I10, and I11 is headerinformation to be added when the MPEG1 coded data is transmitted by RTP.The value P (P=1) of the header information Ic indicates that the datain the data section is I frame data, and the packet containing this Iframe data is to be treated as a high priority packet. The value P (P=2)indicates that the data in the data section is P frame data, and thepacket containing this P frame data is to be treated as a low prioritypacket. The value P(P=3) indicates that the data in the data section isB frame data, and the packet containing this B frame data is to betreated as a low priority packet.

[0378] Further, the extension header information Id corresponds to thesequence number and the priority information of the previous packet inthe third embodiment (refer to FIG. 6), the sequence number and theretransmission count of the previously transmitted high priority packetin the fourth embodiment (refer to FIGS. 13 and 14), the sequence numberand the reproduction time of the previous packet in the secondmodification of the sixth embodiment (refer to FIG. 21), the differencevalue of the sequence number of the previous packet and the differencevalue of the reproduction time of the previous packet in the thirdmodification of the sixth embodiment (refer to FIG. 22), and thetransmitting end high priority sequence number in the ninth embodiment(refer to FIG. 29).

What is claimed is:
 1. A data transmission method for performingcontinuous data transmission from the transmitting end to the receivingend in units of packets, each packet having additional informationrelating to its sequence number, priority, and data reproduction time atthe receiving end, while successively reproducing data of packetsreceived at the receiving end, said method comprising the steps of: atthe transmitting end, giving priority information to each packet to betransmitted and storing, as retransmission data, only data of packetsthe priorities of which are equal to or higher than a predeterminedvalue, in a retransmission buffer; at the receiving end, when atransmission error is detected, detecting the priority information of anerror packet; and when the detected priority is equal to or higher thanthe predetermined value, outputting a retransmission request for theerror packet to the transmitting end by indicating the sequence numberof this error packet; at the transmitting end, only when the data of thepacket having the sequence number which is indicated by theretransmission request from the receiving end is stored in theretransmission buffer, retransmitting the data of this packet to thereceiving end; and discarding the data stored in the retransmissionbuffer in order starting from a packet which cannot be in time for datareproduction at the receiving end.
 2. The data transmission method ofclaim 1 wherein, when the retransmission buffer is filled up to itscapacity, an updation process is performed, in which the retransmissiondata are retained while the data stored in the retransmission buffer arediscarded in order, starting from a packet of the earliest reproductiontime, on the basis of the reproduction time of each packet stored in theretransmission buffer.
 3. The data transmission method of claim 1wherein, when the data transmitted from the transmitting end to thereceiving end is video data based on MPEG, a packet which contains datacorresponding to frames coded by utilizing intra-frame correlation isregarded as a packet having a high priority.
 4. The data transmissionmethod of claim 1 wherein: at the transmitting end, the additionalinformation relating to the sequence number and the priority of apredetermined packet is also embedded in a subsequent packet to betransmitted after the predetermined packet; and at the receiving end, inthe case where a transmission error has occurred in the predeterminedpacket and the additional information of the predetermined packet has anerror, a retransmission request for the predetermined packet as an errorpacket is made on the basis of the additional information of thepredetermined packet which is embedded in the subsequent packet, whenthe subsequent packet transmitted after the predetermined packet isreceived.
 5. The data transmission method of claim 4 wherein: at thetransmitting end, the process of embedding the sequence number of apredetermined high priority packet in a subsequent packet which followsthe predetermined high priority packet is continuously performed until ahigh priority packet next to the predetermined high priority packet istransmitted; and at the receiving end, the sequence number of anotherpacket which is embedded in the received packet is extracted, and whentransmission error has occurred in the packet of the extracted sequencenumber, a retransmission request for this error packet is made byindicating the sequence number of this packet.
 6. A data transmissionapparatus for relaying data which are successively transmitted from thetransmitting end in units of packets, each packet having additionalinformation relating to its sequence number, priority, and datareproduction time at the receiving end, said apparatus comprising: areceiving unit for receiving the packets transmitted from thetransmitting end; a priority decision unit for deciding the priority ofeach the received packets; a retransmission packet storage unit forstoring packets the priorities of which are equal to or higher than apredetermined value, as retransmission packets, on the basis of thepriority of each packet decided by the priority decision unit; aretransmission instruction receiving unit for receiving a retransmissionrequest from a terminal at the receiving end; a retransmission decisionunit for deciding whether retransmission of the packet for which theretransmission request has been made should be performed or not, on thebasis of the retransmission request and the storage status of theretransmission packets in the retransmission packet storage unit atransmission queue management unit for setting the transmission order ofthe received packets and the packets which have been decided as packetsto be retransmitted, on the basis of the additional information; and atransmission unit for transmitting the data of these packets in thetransmission order set by the management unit.
 7. A data receivingapparatus for receiving data which are transmitted from the transmittingend in units of packets, each packet having additional informationrelating to its sequence number, priority, and data reproduction time atthe receiving end and successively reproducing the data for each packet,said apparatus comprising: a receiving unit for receiving the packetstransmitted from the transmitting end; an error packet detection unitfor detecting error packets in which errors have occurred duringtransmission, and outputting normal packets which have been transmittedwithout transmission errors, on the basis of the data of the receivedpackets; a packet priority decision unit for receiving the output fromthe error packet detection unit, and deciding error packets thepriorities of which are equal to or higher than a predetermined value;and a retransmission instruction output unit for outputting aretransmission request for each of the error packets the priorities ofwhich are decided as being equal to or higher than the predeterminedvalue, to the transmitting end, by indicating the sequence number ofthis error packet.
 8. A data transmission method in which datatransmission from the transmitting end to the receiving end iscontinuously performed in units of packets, each packet havingadditional information relating to its sequence number, priority, anddata reproduction time at the receiving end, while successivelyreproducing data of packets which have arrived at the receiving end and,at this time, only packets which can be in time for data reproduction atthe receiving end are retransmitted, said method comprising the stepsof: at the transmitting end, giving a data reproduction time at thereceiving end to each packet to be transmitted; and storing, asretransmission data, only data of packets the priorities of which areequal to or higher than a predetermined value, in a retransmissionbuffer; at the receiving end, when a transmission error is detected,detecting the reproduction time for an error packet and the arrival timeof the error packet, and deciding an arrival time limit in accordancewith the reproduction time; and when the error packet has arrived beforethe arrival time limit, outputting a retransmission request for theerror packet to the transmitting end by indicating the sequence numberof the error packet; at the transmitting end, when the data of thepacket having the sequence number indicated by the retransmissionrequest from the receiving end stored in the retransmission buffer,retransmitting data of the packet the transmission time of which doesnot pass the reproduction time, to the receiving end, while discardingdata of the packet the transmission time of which has passed thereproduction time; and discarding the data stored in the retransmissionbuffer in order starting from a packet which cannot be in time for datareproduction at the receiving end.
 9. The data transmission method ofclaim 8 wherein, when the retransmission buffer is filled up to itscapacity, an updation process is performed, in which the retransmissiondata are retained while the, data stored in the retransmission bufferare discarded in order, starting from a packet of the earliestreproduction time on the basis of the reproduction time of each packetstored in the retransmission buffer.
 10. The data transmission method ofclaim 8 wherein the arrival time limit is decided based on at least oneof the allowable packet delay time decided at the receiving end, and thepacket transmission delay time between the transmitting end and thereceiving end.
 11. The data transmission method of claim 8 wherein: atthe transmitting end, additional information relating to the sequencenumber and the reproduction time corresponding to a target packet to betransmitted is embedded in a subsequent packet to be transmitted afterthe target packet; and at the receiving end, when a transmission errorof the target packet has occurred and the additional information of thetarget packet has an error, a retransmission request for the targetpacket as an error packet is made on the basis of the additionalinformation of the target packet which is embedded in the subsequentpacket, when the subsequent packet transmitted after the target packetis received.
 12. A data transmission apparatus for relaying data whichare successively transmitted from the transmitting end in units ofpackets, each packet having additional information relating to itssequence number, priority, data reproduction time at the receiving end,said apparatus comprising: a receiving unit for receiving the packetstransmitted from the transmitting end; a priority decision unit fordeciding the priority of each the received packets; a reproduction timedecision unit for deciding packets which cannot be in time forreproduction at the receiving end, amongst the packets to be transmittedto the receiving end; a retransmission packet storage unit for storingpackets the priorities of which are equal to or higher than apredetermined value, as retransmission packets, on the basis of thepriority each packet decided by the priority decision unit; aretransmission instruction receiving unit for receiving a retransmissionrequest from a terminal at the receiving end; a retransmission decisionunit for deciding whether retransmission of the packet for which theretransmission request has been made should be performed or not, on thebasis of the retransmission request and the storage status of theretransmission packets in the retransmission packet storage unit; atransmission queue management unit for setting the transmission order ofthe received packets and the packets which have been decided as packetsto be retransmitted, on the basis of the additional information; and atransmission unit for transmitting, in the transmission order set by themanagement unit, the data of packets other than the packets which aredecided as packets that cannot be in time for reproduction at thereceiving end, by the reproduction time decision unit.
 13. A datareceiving apparatus for receiving data which are transmitted from thetransmitting end in units of packets, each packet having additionalinformation relating to its sequence number, priority, and datareproduction time at the receiving end and successively reproducing thedata for each packet, said apparatus comprising: a receiving unit forreceiving the packets transmitted from the transmitting end; an errorpacket detection unit for detecting error packets in which errors haveoccurred during transmission, and outputting normal packets which havebeen transmitted without transmission errors, on the basis of the dataof the received packets; a reproduction time decision unit for detectingthe reproduction time given to each error packet detected by the errorpacket detection unit and the arrival time of the error packet at thereceiving end, and setting the arrival time limit based on thereproduction time, and deciding whether or not the error packet hasarrived at the receiving end before the arrival time limit; and aretransmission instruction output unit for outputting a retransmissionrequest only for the error packet which has arrived at the receiving endbefore the arrival time limit, to the transmitting end, by indicatingthe sequence number of the error packet, on the basis of the result ofthe decision in the reproduction time decision unit.
 14. A datatransmission method for performing continuous data transmission from thetransmitting end to the receiving end in units of packets, each packethaving additional information relating to its sequence number, priority,and data reproduction time at the receiving end, while successivelyreproducing data of packets arrived at the receiving end, said methodcomprising the steps of: at the transmitting end, giving a datareproduction time and priority information to each packet to betransmitted; and storing, as retransmission data, only data of packetsthe priorities of which are equal to or higher than a predeterminedvalue, in a retransmission buffer; at the receiving end, when atransmission error is detected, detecting the priority information of anerror packet, the reproduction time of the error packet, and the arrivaltime of the error packet; setting the arrival time limit of the errorpacket on the basis of the reproduction time; and when the detectedpriority is equal to or higher than the predetermined value and theerror packet has arrived before the arrival time limit, outputting aretransmission request for this error packet to the transmitting end byindicating the sequence number of this error packet; at the transmittingend, when data of the packet having the sequence number indicated by theretransmission request from the receiving end is stored in theretransmission buffer, retransmitting only data of the packet thetransmission time of which does not pass the reproduction time, to thereceiving end, while discarding data of the packet the transmission timeof which has passed the reproduction time; and discarding the datastored in the retransmission buffer in order starting from a packetwhich cannot be in time for reproduction at the receiving end.
 15. Thedata transmission method of claim 14 wherein: at the transmitting end,additional information relating to the sequence number, the priority,and the reproduction time of a predetermined packet is embedded in asubsequent packet to be transmitted after the predetermined packet; andat the receiving end, when a transmission error of the predeterminedpacket has occurred and the additional information of the predeterminedpacket has an error, a retransmission request for the, predeterminedpacket as an error packet is made on the basis of the additionalinformation of the predetermined packet which is embedded in thesubsequent packet, when the subsequent packet transmitted after thepredetermined packet is received.
 16. The data transmission method ofclaim 15 wherein: at the transmitting end, the process of embedding thesequence number of a predetermined high priority packet in a subsequentpacket which follows the predetermined high priority packet iscontinuously performed until a high priority packet next to thepredetermined high priority packet is transmitted; and at the receivingend, the sequence number of another packet which is embedded in thereceived packet is extracted, and when transmission error has occurredin the packet of the extracted sequence number, a retransmission requestfor this packet is made by indicating the sequence number of thispacket.
 17. The data transmission method of claim 15 wherein, at thetransmitting end, when additional information relating to the sequencenumber and the reproduction time corresponding to each packet isembedded in a subsequent packet to be transmitted after the packet, adifference between additional information relating to the sequencenumber and the reproduction time corresponding to the subsequent packetand the additional information relating to the sequence number and thereproduction time corresponding to the previous packet is embedded asthe additional information.
 18. A data transmission method forperforming data transmission between a distribution server and aterminal through a relay server in units of packets, and successivelyreproducing data of packets received at the terminal, said methodcomprising the steps of: when a transmission error has occurred betweenthe relay server and the terminal, performing retransmission of an errorpacket by the relay server in response to a retransmission request fromthe terminal; and when a transmission error has occurred between thedistribution server and the relay server, performing retransmission ofan error packet by the distribution server in response to aretransmission request which has been transmitted from the terminalthrough the relay server.
 19. The data transmission method of claim 18wherein, when a transmission error has occurred between the distributionserver and the relay server, a retransmission request is transmittedfrom the relay server to the distribution server, and retransmission ofan error packet to the relay server is performed by the distributionserver.
 20. A data transmission apparatus for relaying data which aresuccessively transmitted from a distribution server, in units of packetseach having additional information relating to its sequence number,priority, data reproduction time at the receiving end, said apparatuscomprising: a receiving unit for receiving the packets transmitted fromthe transmitting end; a priority decision unit for deciding the priorityof each of the received packets; a retransmission packet storage unitfor storing packets the priorities of which are equal to or higher thana predetermined value, as retransmission packets, on the basis of thepriority of each packet decided by the priority decision unit; aretransmission instruction receiving unit for receiving a retransmissionrequest from a terminal at the receiving end; a retransmission decisionunit for deciding whether retransmission of the packet for which theretransmission request has been made is to be performed or not, on thebasis of the retransmission request and the storage status of theretransmission packets in the retransmission packet storage unit aretransmission instruction output unit for outputting the retransmissionrequest for the error packet requested by the terminal, to thedistribution server, on the basis of the result of the decision in theretransmission decision unit; a transmission queue management unit forsetting the transmission order of the received packets and the packetswhich have been decided as packets to be retransmitted on the basis theadditional information; and a transmission unit for transmitting thedata of these packets in the transmission order set by the managementunit.
 21. A data transmission method for performing continuous datatransmission from the transmitting end to the receiving end in units ofpackets, each packet having additional information relating to itssequence number, priority, and data reproduction time at the receivingend, while successively reproducing data packets received at thereceiving end, said method comprising the steps of: at the transmittingend, when a packet the priority of which is equal to or higher than apredetermined value is transmitted as a high priority packet, storingdata of this high priority packet, as retransmission data, in aretransmission buffer; managing the value of the transmitting end highpriority sequence number which corresponds to the number of transmittedhigh priority packets, and the value of the sequence number of the highpriority packet so that these values are correlated with each other; andtransmitting a subsequent packet which follows the high priority packetafter embedding the value of the transmitting end high priority sequencenumber in this subsequent packet; at the receiving end, extracting thevalue of the transmitting end high priority sequence number which isembedded in the received packet; managing the value of the receiving endhigh priority sequence number which corresponds to the number ofreceived high priority packets; when the value of the extractedtransmitting end high priority sequence number is not equal to the valueof the receiving end high priority sequence number, outputting aretransmission request, to the transmitting end, by indicating the valueof the transmitting end high priority sequence number which is obtainedon the basis of the value of the receiving end high priority sequencenumber; and updating the value of the receiving end high prioritysequence number; at the transmitting end, only when data of the packethaving the sequence number corresponding to the value of thetransmitting end high priority sequence number which is indicated by theretransmission request from the receiving end is stored in theretransmission buffer, retransmitting the data of this packet to thereceiving end.
 22. The data transmission method of claim 21, wherein: atthe receiving end, when the value of the transmitting end high prioritysequence number embedded in the received packet is not equal to thevalue of the receiving end high priority, sequence number, aretransmission request is output to the transmitting end, by listing thevalues ranging from the value obtained by adding 1 to the receiving endhigh priority sequence number, to the value of the transmitting end highpriority sequence number, as the values of the transmitting end highpriority sequence numbers, or by designating the range as the range ofthe values of the transmitting end high priority sequence numbers; andat the transmitting end, the sequence numbers corresponding to thevalues of the plural transmitting end high priority sequence numberswhich are indicated by the retransmission request from the receiving endare retrieved, and only when data of the packets having the sequencenumbers obtained by the retrieval are stored in the retransmissionbuffer, the data of the packets are retransmitted to the receiving end.23. The data transmission method of claim 21 wherein: at the receivingend, the retransmission request is performed continuously be severaltimes, indicating the value of a transmitting end high priority sequencenumber; and at the transmitting end, the sequence number correspondingto the value of the transmitting end high priority sequence number whichis indicated by the retransmission request from the receiving end isretrieved, and data of the packet having the sequence number obtained bythe retrieval is retransmitted to the receiving end and, simultaneously,the correspondence between the value of the sequence number obtained bythe retrieval and the value of the transmitting end high prioritysequence number indicated by the receiving end is deleted.
 24. A datatransmission apparatus for relaying data which are successivelytransmitted from the transmitting end in units of packets, each packethaving additional information relating to its sequence number, priority,data reproduction time at the receiving end, said apparatus comprising:a receiving unit for receiving the packets transmitted from thetransmitting end; a transmission queue management unit for setting thetransmission order of the received packets and packets which are decidedas packets to be retransmitted; a transmission unit for transmittingdata of these packets in the transmission order set by the transmissionqueue management unit; a priority decision unit for deciding thepriority of each the received packets; a retransmission packet storageunit for storing packets the priorities of which are equal to or higherthan a predetermined value, as retransmission packets, on the basis ofthe priority of each packet decided by the priority decision unit; asequence number management unit for managing the value of thetransmitting end high priority sequence number which corresponds to thenumber of transmitted high priority packets, and the value of thesequence number of the high priority packet so that these values arecorrelated with each other; a high priority sequence number insertionunit for embedding the value of the transmitting end high prioritysequence number in a subsequent packet which follows the high prioritypacket; a retransmission instruction receiving unit for receiving aretransmission request indicating the high priority sequence number,from a terminal at the transmitting end; and a retransmission decisionunit for deciding whether retransmission of the packet for which theretransmission request has been made is to be performed or notion thebasis of the retransmission request and the storage status of theretransmission packets in the retransmission packet storage unit
 25. Adata receiving apparatus for receiving data which are transmitted fromthe transmitting end in units of packets, each packet having additionalinformation relating to its sequence number, priority, and datareproduction time at the receiving end and successively reproducing thedata for each packet, said apparatus comprising: a receiving unit forreceiving the packets transmitted from the transmitting end; an errorpacket detection unit for detecting an error packet which an error hasoccurred during transmission, and outputting a normal packet which hasbeen transmitted without transmission errors, and the value of thetransmitting end high priority sequence number which corresponds to thenumber of transmitted high priority packets and is embedded in thenormal packet; a high priority sequence number management unit formanaging the value of the receiving end high priority sequence numberwhich corresponds to the number of normal high priority packets whichhave been received without transmission errors, on the basis of theoutput from the error packet detection unit; a retransmission sequencenumber decision unit for comparing the value of the transmitting endhigh priority sequence number from the error packet detection unit withthe value of the receiving end high priority sequence number and whenthese values are not equal, deciding the value of the transmitting endhigh priority sequence number for which a retransmission request is tobe made, on the basis of the value of the receiving end high prioritysequence number; and a retransmission instruction output unit foroutputting a retransmission request to the transmitting end, byindicating the value of the decided transmitting end high prioritysequence number.
 26. A data structure of a packet for performing datatransmission from the retransmitting end and the receiving end, wherein:said packet comprises a header section containing relevant informationindicating the attribute of the packet, and a data section containingdata to be transmitted; and said header section comprises at least firstand second header information, amongst first header informationindicating the sequence number corresponding to the packet, secondheader information indicating the priority of the packet, and thirdheader information indicating the reproduction time at the receivingend, of the data to be transmitted.
 27. The packet data structure ofclaim 26 wherein the header section of the packet includes attributeinformation of a packet which has already been transmitted before thepacket.
 28. The packet data structure of claim 27 wherein the headersection of the packet includes the first and second information or thefirst and third information, as attribute information of packet whichhas already been transmitted before the packet.
 29. The packet datastructure of claim 26 wherein the header section of the packet includesthe value of the high priority sequence number corresponding to thenumber of high priority packets which have been transmitted before thepacket and having the priorities equal to or higher than a predeterminedvalue.